Internet Engineering Task Force (IETF) S. Josefsson
Request for Comments: 7468 SJD AB
Category: Standards Track S. Leonard
ISSN: 2070-1721 Penango, Inc.
April 2015
Textual Encodings of PKIX, PKCS, and CMS Structures
Abstract
This document describes and discusses the textual encodings of the
Public-Key Infrastructure X.509 (PKIX), Public-Key Cryptography
Standards (PKCS), and Cryptographic Message Syntax (CMS). The
textual encodings are well-known, are implemented by several
applications and libraries, and are widely deployed. This document
articulates the de facto rules by which existing implementations
operate and defines them so that future implementations can
interoperate.
Status of This Memo
This is an Internet Standards Track document.
This document is a product of the Internet Engineering Task Force
(IETF). It represents the consensus of the IETF community. It has
received public review and has been approved for publication by the
Internet Engineering Steering Group (IESG). Further information on
Internet Standards is available in Section 2 of RFC 5741.
Information about the current status of this document, any errata,
and how to provide feedback on it may be obtained at
http://www.rfc-editor.org/info/rfc7468.
Copyright Notice
Copyright (c) 2015 IETF Trust and the persons identified as the
document authors. All rights reserved.
This document is subject to BCP 78 and the IETF Trust's Legal
Provisions Relating to IETF Documents
(http://trustee.ietf.org/license-info) in effect on the date of
publication of this document. Please review these documents
carefully, as they describe your rights and restrictions with respect
to this document. Code Components extracted from this document must
include Simplified BSD License text as described in Section 4.e of
the Trust Legal Provisions and are provided without warranty as
described in the Simplified BSD License.
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RFC 7468 PKIX Textual Encodings April 2015
Table of Contents
1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . 2
2. General Considerations . . . . . . . . . . . . . . . . . . . 3
3. ABNF . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5
4. Guide . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7
5. Textual Encoding of Certificates . . . . . . . . . . . . . . 8
5.1. Encoding . . . . . . . . . . . . . . . . . . . . . . . . 8
5.2. Explanatory Text . . . . . . . . . . . . . . . . . . . . 9
5.3. File Extension . . . . . . . . . . . . . . . . . . . . . 9
6. Textual Encoding of Certificate Revocation Lists . . . . . . 10
7. Textual Encoding of PKCS #10 Certification Request Syntax . . 11
8. Textual Encoding of PKCS #7 Cryptographic Message Syntax . . 11
9. Textual Encoding of Cryptographic Message Syntax . . . . . . 12
10. One Asymmetric Key and the Textual Encoding of PKCS #8
Private Key Info . . . . . . . . . . . . . . . . . . . . . . 12
11. Textual Encoding of PKCS #8 Encrypted Private Key Info . . . 13
12. Textual Encoding of Attribute Certificates . . . . . . . . . 13
13. Textual Encoding of Subject Public Key Info . . . . . . . . . 14
14. Security Considerations . . . . . . . . . . . . . . . . . . . 14
15. References . . . . . . . . . . . . . . . . . . . . . . . . . 14
15.1. Normative References . . . . . . . . . . . . . . . . . . 14
15.2. Informative References . . . . . . . . . . . . . . . . . 15
Appendix A. Non-conforming Examples . . . . . . . . . . . . . . 17
Appendix B. DER Expectations . . . . . . . . . . . . . . . . . . 18
Acknowledgements . . . . . . . . . . . . . . . . . . . . . . . . 19
Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . 20
1. Introduction
Several security-related standards used on the Internet define ASN.1
data formats that are normally encoded using the Basic Encoding Rules
(BER) or Distinguished Encoding Rules (DER) [X.690], which are
binary, octet-oriented encodings. This document is about the textual
encodings of the following formats:
1. Certificates, Certificate Revocation Lists (CRLs), and Subject
Public Key Info structures in the Internet X.509 Public Key
Infrastructure Certificate and Certificate Revocation List (CRL)
Profile [RFC5280].
2. PKCS #10: Certification Request Syntax [RFC2986].
3. PKCS #7: Cryptographic Message Syntax [RFC2315].
4. Cryptographic Message Syntax [RFC5652].
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5. PKCS #8: Private-Key Information Syntax [RFC5208], renamed to One
Asymmetric Key in Asymmetric Key Package [RFC5958], and Encrypted
Private-Key Information Syntax in the same documents.
6. Attribute Certificates in An Internet Attribute Certificate
Profile for Authorization [RFC5755].
A disadvantage of a binary data format is that it cannot be
interchanged in textual transports, such as email or text documents.
One advantage with text-based encodings is that they are easy to
modify using common text editors; for example, a user may concatenate
several certificates to form a certificate chain with copy-and-paste
operations.
The tradition within the RFC series can be traced back to Privacy-
Enhanced Mail (PEM) [RFC1421], based on a proposal by Marshall Rose
in Message Encapsulation [RFC934]. Originally called "PEM
encapsulation mechanism", "encapsulated PEM message", or (arguably)
"PEM printable encoding", today the format is sometimes referred to
as "PEM encoding". Variations include OpenPGP ASCII armor [RFC4880]
and OpenSSH key file format [RFC4716].
For reasons that basically boil down to non-coordination or
inattention, many PKIX, PKCS, and CMS libraries implement a text-
based encoding that is similar to -- but not identical with -- PEM
encoding. This document specifies the _textual encoding_ format,
articulates the de facto rules that most implementations operate by,
and provides recommendations that will promote interoperability going
forward. This document also provides common nomenclature for syntax
elements, reflecting the evolution of this de facto standard format.
Peter Gutmann's "X.509 Style Guide" [X.509SG] contains a section
"base64 Encoding" that describes the formats and contains suggestions
similar to what is in this document. All figures are real,
functional examples, with key lengths and inner contents chosen to be
as small as practicable.
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
"SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED", "MAY", and
"OPTIONAL" in this document are to be interpreted as described in RFC
2119 [RFC2119].
2. General Considerations
Textual encoding begins with a line comprising "-----BEGIN ", a
label, and "-----", and ends with a line comprising "-----END ", a
label, and "-----". Between these lines, or "encapsulation
boundaries", are base64-encoded data according to Section 4 of
[RFC4648]. (PEM [RFC1421] referred to this data as the "encapsulated
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RFC 7468 PKIX Textual Encodings April 2015
text portion".) Data before the encapsulation boundaries are
permitted, and parsers MUST NOT malfunction when processing such
data. Furthermore, parsers SHOULD ignore whitespace and other non-
base64 characters and MUST handle different newline conventions.
The type of data encoded is labeled depending on the type label in
the "-----BEGIN " line (pre-encapsulation boundary). For example,
the line may be "-----BEGIN CERTIFICATE-----" to indicate that the
content is a PKIX certificate (see further below). Generators MUST
put the same label on the "-----END " line (post-encapsulation
boundary) as the corresponding "-----BEGIN " line. Labels are
formally case-sensitive, uppercase, and comprised of zero or more
characters; they do not contain consecutive spaces or hyphen-minuses,
nor do they contain spaces or hyphen-minuses at either end. Parsers
MAY disregard the label in the post-encapsulation boundary instead of
signaling an error if there is a label mismatch: some extant
implementations require the labels to match; others do not.
There is exactly one space character (SP) separating the "BEGIN" or
"END" from the label. There are exactly five hyphen-minus (also
known as dash) characters ("-") on both ends of the encapsulation
boundaries, no more, no less.
The label type implies that the encoded data follows the specified
syntax. Parsers MUST handle non-conforming data gracefully.
However, not all parsers or generators prior to this document behave
consistently. A conforming parser MAY interpret the contents as
another label type but ought to be aware of the security implications
discussed in the Security Considerations section. The labels
described in this document identify container formats that are not
specific to any particular cryptographic algorithm, a property
consistent with algorithm agility. These formats use the ASN.1
AlgorithmIdentifier structure as described in Section 4.1.1.2 of
[RFC5280].
Unlike legacy PEM encoding [RFC1421], OpenPGP ASCII armor, and the
OpenSSH key file format, textual encoding does *not* define or permit
headers to be encoded alongside the data. Empty space can appear
between the pre-encapsulation boundary and the base64, but generators
SHOULD NOT emit such any such spacing. (The provision for this empty
area is a throwback to PEM, which defined an "encapsulated header
portion".)
Implementers need to be aware that extant parsers diverge
considerably on the handling of whitespace. In this document,
"whitespace" means any character or series of characters that
represent horizontal or vertical space in typography. In US-ASCII,
whitespace means HT (0x09), VT (0x0B), FF (0x0C), SP (0x20), CR
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RFC 7468 PKIX Textual Encodings April 2015
(0x0D), and LF (0x0A); "blank" means HT and SP; lines are divided
with CRLF, CR, or LF. The common ABNF production WSP is congruent
with "blank"; a new production W is used for "whitespace". The ABNF
in Section 3 is specific to US-ASCII. As these textual encodings can
be used on many different systems as well as on long-term archival
storage media such as paper or engravings, an implementer ought to
use the spirit rather than the letter of the rules when generating or
parsing these formats in environments that are not strictly limited
to US-ASCII.
Most extant parsers ignore blanks at the ends of lines; blanks at the
beginnings of lines or in the middle of the base64-encoded data are
far less compatible. These observations are codified in Figure 1.
The most lax parser implementations are not line-oriented at all and
will accept any mixture of whitespace outside of the encapsulation
boundaries (see Figure 2). Such lax parsing may run the risk of
accepting text that was not intended to be accepted in the first
place (e.g., because the text was a snippet or sample).
Generators MUST wrap the base64-encoded lines so that each line
consists of exactly 64 characters except for the final line, which
will encode the remainder of the data (within the 64-character line
boundary), and they MUST NOT emit extraneous whitespace. Parsers MAY
handle other line sizes. These requirements are consistent with PEM
[RFC1421].
Files MAY contain multiple textual encoding instances. This is used,
for example, when a file contains several certificates. Whether the
instances are ordered or unordered depends on the context.
3. ABNF
The ABNF [RFC5234] of the textual encoding is:
textualmsg = preeb *WSP eol
*eolWSP
base64text
posteb *WSP [eol]
preeb = "-----BEGIN " label "-----" ; unlike [RFC1421] (A)BNF,
; eol is not required (but
posteb = "-----END " label "-----" ; see [RFC1421], Section 4.4)
base64char = ALPHA / DIGIT / "+" / "/"
base64pad = "="
base64line = 1*base64char *WSP eol
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base64finl = *base64char (base64pad *WSP eol base64pad /
*2base64pad) *WSP eol
; ...AB= <EOL> = <EOL> is not good, but is valid
base64text = *base64line base64finl
; we could also use <encbinbody> from RFC 1421, which requires
; 16 groups of 4 chars, which means exactly 64 chars per
; line, except the final line, but this is more accurate
labelchar = %x21-2C / %x2E-7E ; any printable character,
; except hyphen-minus
label = [ labelchar *( ["-" / SP] labelchar ) ] ; empty ok
eol = CRLF / CR / LF
eolWSP = WSP / CR / LF ; compare with LWSP
Figure 1: ABNF (Standard)
laxtextualmsg = *W preeb
laxbase64text
posteb *W
W = WSP / CR / LF / %x0B / %x0C ; whitespace
laxbase64text = *(W / base64char) [base64pad *W [base64pad *W]]
Figure 2: ABNF (Lax)
stricttextualmsg = preeb eol
strictbase64text
posteb eol
strictbase64finl = *15(4base64char) (4base64char / 3base64char
base64pad / 2base64char 2base64pad) eol
base64fullline = 64base64char eol
strictbase64text = *base64fullline strictbase64finl
Figure 3: ABNF (Strict)
New implementations SHOULD emit the strict format (Figure 3)
specified above. The choice of parsing strategy depends on the
context of use.
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4. Guide
For convenience, these figures summarize the structures, encodings,
and references in the following sections:
Sec. Label ASN.1 Type Reference Module
----+----------------------+-----------------------+---------+----------
5 CERTIFICATE Certificate [RFC5280] id-pkix1-e
6 X509 CRL CertificateList [RFC5280] id-pkix1-e
7 CERTIFICATE REQUEST CertificationRequest [RFC2986] id-pkcs10
8 PKCS7 ContentInfo [RFC2315] id-pkcs7*
9 CMS ContentInfo [RFC5652] id-cms2004
10 PRIVATE KEY PrivateKeyInfo ::= [RFC5208] id-pkcs8
OneAsymmetricKey [RFC5958] id-aKPV1
11 ENCRYPTED PRIVATE KEY EncryptedPrivateKeyInfo [RFC5958] id-aKPV1
12 ATTRIBUTE CERTIFICATE AttributeCertificate [RFC5755] id-acv2
13 PUBLIC KEY SubjectPublicKeyInfo [RFC5280] id-pkix1-e
Figure 4: Convenience Guide
-----------------------------------------------------------------------
id-pkixmod OBJECT IDENTIFIER ::= {iso(1) identified-organization(3)
dod(6) internet(1) security(5) mechanisms(5) pkix(7) mod(0)}
id-pkix1-e OBJECT IDENTIFIER ::= {id-pkixmod pkix1-explicit(18)}
id-acv2 OBJECT IDENTIFIER ::= {id-pkixmod mod-attribute-cert-v2(61)}
id-pkcs OBJECT IDENTIFIER ::= {iso(1) member-body(2) us(840)
rsadsi(113549) pkcs(1)}
id-pkcs10 OBJECT IDENTIFIER ::= {id-pkcs 10 modules(1) pkcs-10(1)}
id-pkcs7 OBJECT IDENTIFIER ::= {id-pkcs 7 modules(0) pkcs-7(1)}
id-pkcs8 OBJECT IDENTIFIER ::= {id-pkcs 8 modules(1) pkcs-8(1)}
id-sm-mod OBJECT IDENTIFIER ::= {id-pkcs 9 smime(16) modules(0)}
id-aKPV1 OBJECT IDENTIFIER ::= {id-sm-mod mod-asymmetricKeyPkgV1(50)}
id-cms2004 OBJECT IDENTIFIER ::= {id-sm-mod cms-2004(24)}
* This OID does not actually appear in PKCS #7 v1.5 [RFC2315]. It
was defined in the ASN.1 module to PKCS #7 v1.6 [P7v1.6], and has
been carried forward through PKCS #12 [RFC7292].
Figure 5: ASN.1 Module Object Identifier Value Assignments
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RFC 7468 PKIX Textual Encodings April 2015
5. Textual Encoding of Certificates
5.1. Encoding
Public-key certificates are encoded using the "CERTIFICATE" label.
The encoded data MUST be a BER (DER strongly preferred; see
Appendix B) encoded ASN.1 Certificate structure as described in
Section 4 of [RFC5280].
-----BEGIN CERTIFICATE-----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-----END CERTIFICATE-----
Figure 6: Certificate Example
Historically, the label "X509 CERTIFICATE" and also less commonly
"X.509 CERTIFICATE" have been used. Generators conforming to this
document MUST generate "CERTIFICATE" labels and MUST NOT generate
"X509 CERTIFICATE" or "X.509 CERTIFICATE" labels. Parsers SHOULD NOT
treat "X509 CERTIFICATE" or "X.509 CERTIFICATE" as equivalent to
"CERTIFICATE", but a valid exception may be for backwards
compatibility (potentially together with a warning).
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5.2. Explanatory Text
Many tools are known to emit explanatory text before the BEGIN and
after the END lines for PKIX certificates, more than any other type.
If emitted, such text SHOULD be related to the certificate, such as
providing a textual representation of key data elements in the
certificate.
Subject: CN=Atlantis
Issuer: CN=Atlantis
Validity: from 7/9/2012 3:10:38 AM UTC to 7/9/2013 3:10:37 AM UTC
-----BEGIN CERTIFICATE-----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-----END CERTIFICATE-----
Figure 7: Certificate Example with Explanatory Text
5.3. File Extension
Although textual encodings of PKIX structures can occur anywhere,
many tools are known to offer an option to output this encoding when
serializing PKIX structures. To promote interoperability and to
separate DER encodings from textual encodings, the extension ".crt"
SHOULD be used for the textual encoding of a certificate.
Implementations should be aware that in spite of this recommendation,
many tools still default to encode certificates in this textual
encoding with the extension ".cer".
This section does not disturb the official application/pkix-cert
registration [RFC2585] in any way (which states that "each '.cer'
file contains exactly one certificate, encoded in DER format"), but
merely articulates a widespread, de facto alternative.
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RFC 7468 PKIX Textual Encodings April 2015
6. Textual Encoding of Certificate Revocation Lists
Certificate Revocation Lists (CRLs) are encoded using the "X509 CRL"
label. The encoded data MUST be a BER (DER strongly preferred; see
Appendix B) encoded ASN.1 CertificateList structure as described in
Section 5 of [RFC5280].
-----BEGIN X509 CRL-----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-----END X509 CRL-----
Figure 8: CRL Example
Historically, the label "CRL" has rarely been used. Today, it is not
common and many popular tools do not understand the label.
Therefore, this document standardizes "X509 CRL" in order to promote
interoperability and backwards-compatibility. Generators conforming
to this document MUST generate "X509 CRL" labels and MUST NOT
generate "CRL" labels. Parsers SHOULD NOT treat "CRL" as equivalent
to "X509 CRL".
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7. Textual Encoding of PKCS #10 Certification Request Syntax
PKCS #10 Certification Requests are encoded using the
"CERTIFICATE REQUEST" label. The encoded data MUST be a BER (DER
strongly preferred; see Appendix B) encoded ASN.1
CertificationRequest structure as described in [RFC2986].
-----BEGIN CERTIFICATE REQUEST-----
MIIBWDCCAQcCAQAwTjELMAkGA1UEBhMCU0UxJzAlBgNVBAoTHlNpbW9uIEpvc2Vm
c3NvbiBEYXRha29uc3VsdCBBQjEWMBQGA1UEAxMNam9zZWZzc29uLm9yZzBOMBAG
ByqGSM49AgEGBSuBBAAhAzoABLLPSkuXY0l66MbxVJ3Mot5FCFuqQfn6dTs+9/CM
EOlSwVej77tj56kj9R/j9Q+LfysX8FO9I5p3oGIwYAYJKoZIhvcNAQkOMVMwUTAY
BgNVHREEETAPgg1qb3NlZnNzb24ub3JnMAwGA1UdEwEB/wQCMAAwDwYDVR0PAQH/
BAUDAwegADAWBgNVHSUBAf8EDDAKBggrBgEFBQcDATAKBggqhkjOPQQDAgM/ADA8
AhxBvfhxPFfbBbsE1NoFmCUczOFApEuQVUw3ZP69AhwWXk3dgSUsKnuwL5g/ftAY
dEQc8B8jAcnuOrfU
-----END CERTIFICATE REQUEST-----
Figure 9: PKCS #10 Example
The label "NEW CERTIFICATE REQUEST" is also in wide use. Generators
conforming to this document MUST generate "CERTIFICATE REQUEST"
labels. Parsers MAY treat "NEW CERTIFICATE REQUEST" as equivalent to
"CERTIFICATE REQUEST".
8. Textual Encoding of PKCS #7 Cryptographic Message Syntax
PKCS #7 Cryptographic Message Syntax structures are encoded using the
"PKCS7" label. The encoded data MUST be a BER-encoded ASN.1
ContentInfo structure as described in [RFC2315].
-----BEGIN PKCS7-----
MIHjBgsqhkiG9w0BCRABF6CB0zCB0AIBADFho18CAQCgGwYJKoZIhvcNAQUMMA4E
CLfrI6dr0gUWAgITiDAjBgsqhkiG9w0BCRADCTAUBggqhkiG9w0DBwQIZpECRWtz
u5kEGDCjerXY8odQ7EEEromZJvAurk/j81IrozBSBgkqhkiG9w0BBwEwMwYLKoZI
hvcNAQkQAw8wJDAUBggqhkiG9w0DBwQI0tCBcU09nxEwDAYIKwYBBQUIAQIFAIAQ
OsYGYUFdAH0RNc1p4VbKEAQUM2Xo8PMHBoYdqEcsbTodlCFAZH4=
-----END PKCS7-----
Figure 10: PKCS #7 Example
The label "CERTIFICATE CHAIN" has been in use to denote a degenerate
PKCS #7 structure that contains only a list of certificates (see
Section 9 of [RFC2315]). Several modern tools do not support this
label. Generators MUST NOT generate the "CERTIFICATE CHAIN" label.
Parsers SHOULD NOT treat "CERTIFICATE CHAIN" as equivalent to
"PKCS7".
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PKCS #7 is an old specification that has long been superseded by CMS
[RFC5652]. Implementations SHOULD NOT generate PKCS #7 when CMS is
an alternative.
9. Textual Encoding of Cryptographic Message Syntax
Cryptographic Message Syntax structures are encoded using the "CMS"
label. The encoded data MUST be a BER-encoded ASN.1 ContentInfo
structure as described in [RFC5652].
-----BEGIN CMS-----
MIGDBgsqhkiG9w0BCRABCaB0MHICAQAwDQYLKoZIhvcNAQkQAwgwXgYJKoZIhvcN
AQcBoFEET3icc87PK0nNK9ENqSxItVIoSa0o0S/ISczMs1ZIzkgsKk4tsQ0N1nUM
dvb05OXi5XLPLEtViMwvLVLwSE0sKlFIVHAqSk3MBkkBAJv0Fx0=
-----END CMS-----
Figure 11: CMS Example
CMS is the IETF successor to PKCS #7. Section 1.1.1 of [RFC5652]
describes the changes since PKCS #7 v1.5. Implementations SHOULD
generate CMS when it is an alternative, promoting interoperability
and forwards-compatibility.
10. One Asymmetric Key and the Textual Encoding of PKCS #8 Private Key
Info
Unencrypted PKCS #8 Private Key Information Syntax structures
(PrivateKeyInfo), renamed to Asymmetric Key Packages
(OneAsymmetricKey), are encoded using the "PRIVATE KEY" label. The
encoded data MUST be a BER (DER preferred; see Appendix B) encoded
ASN.1 PrivateKeyInfo structure as described in PKCS #8 [RFC5208], or
a OneAsymmetricKey structure as described in [RFC5958]. The two are
semantically identical and can be distinguished by version number.
-----BEGIN PRIVATE KEY-----
MIGEAgEAMBAGByqGSM49AgEGBSuBBAAKBG0wawIBAQQgVcB/UNPxalR9zDYAjQIf
jojUDiQuGnSJrFEEzZPT/92hRANCAASc7UJtgnF/abqWM60T3XNJEzBv5ez9TdwK
H0M6xpM2q+53wmsN/eYLdgtjgBd3DBmHtPilCkiFICXyaA8z9LkJ
-----END PRIVATE KEY-----
Figure 12: PKCS #8 PrivateKeyInfo (OneAsymmetricKey) Example
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11. Textual Encoding of PKCS #8 Encrypted Private Key Info
Encrypted PKCS #8 Private Key Information Syntax structures
(EncryptedPrivateKeyInfo), called the same in [RFC5958], are encoded
using the "ENCRYPTED PRIVATE KEY" label. The encoded data MUST be a
BER (DER preferred; see Appendix B) encoded ASN.1
EncryptedPrivateKeyInfo structure as described in PKCS #8 [RFC5208]
and [RFC5958].
-----BEGIN ENCRYPTED PRIVATE KEY-----
MIHNMEAGCSqGSIb3DQEFDTAzMBsGCSqGSIb3DQEFDDAOBAghhICA6T/51QICCAAw
FAYIKoZIhvcNAwcECBCxDgvI59i9BIGIY3CAqlMNBgaSI5QiiWVNJ3IpfLnEiEsW
Z0JIoHyRmKK/+cr9QPLnzxImm0TR9s4JrG3CilzTWvb0jIvbG3hu0zyFPraoMkap
8eRzWsIvC5SVel+CSjoS2mVS87cyjlD+txrmrXOVYDE+eTgMLbrLmsWh3QkCTRtF
QC7k0NNzUHTV9yGDwfqMbw==
-----END ENCRYPTED PRIVATE KEY-----
Figure 13: PKCS #8 EncryptedPrivateKeyInfo Example
12. Textual Encoding of Attribute Certificates
Attribute certificates are encoded using the "ATTRIBUTE CERTIFICATE"
label. The encoded data MUST be a BER (DER strongly preferred; see
Appendix B) encoded ASN.1 AttributeCertificate structure as described
in [RFC5755].
-----BEGIN ATTRIBUTE CERTIFICATE-----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-----END ATTRIBUTE CERTIFICATE-----
Figure 14: Attribute Certificate Example
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13. Textual Encoding of Subject Public Key Info
Public keys are encoded using the "PUBLIC KEY" label. The encoded
data MUST be a BER (DER preferred; see Appendix B) encoded ASN.1
SubjectPublicKeyInfo structure as described in Section 4.1.2.7 of
[RFC5280].
-----BEGIN PUBLIC KEY-----
MHYwEAYHKoZIzj0CAQYFK4EEACIDYgAEn1LlwLN/KBYQRVH6HfIMTzfEqJOVztLe
kLchp2hi78cCaMY81FBlYs8J9l7krc+M4aBeCGYFjba+hiXttJWPL7ydlE+5UG4U
Nkn3Eos8EiZByi9DVsyfy9eejh+8AXgp
-----END PUBLIC KEY-----
Figure 15: Subject Public Key Info Example
14. Security Considerations
Data in this format often originates from untrusted sources, thus
parsers must be prepared to handle unexpected data without causing
security vulnerabilities.
Implementers building implementations that rely on canonical
representation or the ability to fingerprint a particular data object
need to understand that this document does not define canonical
encodings. The first ambiguity is introduced by permitting the text-
encoded representation instead of the binary BER or DER encodings,
but further ambiguities arise when multiple labels are treated as
similar. Variations of whitespace and non-base64 alphabetic
characters can create further ambiguities. Data encoding ambiguities
also create opportunities for side channels. If canonical encodings
are desired, the encoded structure must be decoded and processed into
a canonical form (namely, DER encoding).
15. References
15.1. Normative References
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119, March 1997,
<http://www.rfc-editor.org/info/rfc2119>.
[RFC2315] Kaliski, B., "PKCS #7: Cryptographic Message Syntax
Version 1.5", RFC 2315, March 1998,
<http://www.rfc-editor.org/info/rfc2315>.
[RFC2986] Nystrom, M. and B. Kaliski, "PKCS #10: Certification
Request Syntax Specification Version 1.7", RFC 2986,
November 2000, <http://www.rfc-editor.org/info/rfc2986>.
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[RFC4648] Josefsson, S., "The Base16, Base32, and Base64 Data
Encodings", RFC 4648, October 2006,
<http://www.rfc-editor.org/info/rfc4648>.
[RFC5280] Cooper, D., Santesson, S., Farrell, S., Boeyen, S.,
Housley, R., and W. Polk, "Internet X.509 Public Key
Infrastructure Certificate and Certificate Revocation List
(CRL) Profile", RFC 5280, May 2008,
<http://www.rfc-editor.org/info/rfc5280>.
[RFC5234] Crocker, D., Ed. and P. Overell, "Augmented BNF for Syntax
Specifications: ABNF", STD 68, RFC 5234, January 2008,
<http://www.rfc-editor.org/info/rfc5234>.
[RFC5652] Housley, R., "Cryptographic Message Syntax (CMS)", STD 70,
RFC 5652, September 2009,
<http://www.rfc-editor.org/info/rfc5652>.
[RFC5755] Farrell, S., Housley, R., and S. Turner, "An Internet
Attribute Certificate Profile for Authorization", RFC
5755, January 2010,
<http://www.rfc-editor.org/info/rfc5755>.
[RFC5958] Turner, S., "Asymmetric Key Packages", RFC 5958, August
2010, <http://www.rfc-editor.org/info/rfc5958>.
[X.690] International Telecommunications Union, "Information
Technology - ASN.1 encoding rules: Specification of Basic
Encoding Rules (BER), Canonical Encoding Rules (CER) and
Distinguished Encoding Rules (DER)", ITU-T Recommendation
X.690, ISO/IEC 8825-1:2008, November 2008.
15.2. Informative References
[RFC934] Rose, M. and E. Stefferud, "Proposed standard for message
encapsulation", RFC 934, January 1985,
<http://www.rfc-editor.org/info/rfc934>.
[RFC1421] Linn, J., "Privacy Enhancement for Internet Electronic
Mail: Part I: Message Encryption and Authentication
Procedures", RFC 1421, February 1993,
<http://www.rfc-editor.org/info/rfc1421>.
[RFC2585] Housley, R. and P. Hoffman, "Internet X.509 Public Key
Infrastructure Operational Protocols: FTP and HTTP", RFC
2585, May 1999, <http://www.rfc-editor.org/info/rfc2585>.
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[RFC4716] Galbraith, J. and R. Thayer, "The Secure Shell (SSH)
Public Key File Format", RFC 4716, November 2006,
<http://www.rfc-editor.org/info/rfc4716>.
[RFC4880] Callas, J., Donnerhacke, L., Finney, H., Shaw, D., and R.
Thayer, "OpenPGP Message Format", RFC 4880, November 2007,
<http://www.rfc-editor.org/info/rfc4880>.
[RFC5208] Kaliski, B., "Public-Key Cryptography Standards (PKCS) #8:
Private-Key Information Syntax Specification Version 1.2",
RFC 5208, May 2008,
<http://www.rfc-editor.org/info/rfc5208>.
[RFC7292] Moriarty, K., Ed., Nystrom, M., Parkinson, S., Rusch, A.,
and M. Scott, "PKCS #12: Personal Information Exchange
Syntax v1.1", RFC 7292, July 2014,
<http://www.rfc-editor.org/info/rfc7292>.
[P7v1.6] Kaliski, B. and K. Kingdon, "Extensions and Revisions to
PKCS #7 (Version 1.6 Bulletin)", May 1997,
<http://www.emc.com/emc-plus/rsa-labs/
standards-initiatives/pkcs-7-cryptographic-message-
syntax-standar.htm>.
[X.509SG] Gutmann, P., "X.509 Style Guide", October 2000,
<http://www.cs.auckland.ac.nz/~pgut001/pubs/
x509guide.txt>.
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Appendix A. Non-conforming Examples
This appendix contains examples for the non-recommended label
variants described earlier in this document. As discussed earlier,
supporting these is not required and is sometimes discouraged.
Still, they can be useful for interoperability testing and for easy
reference.
-----BEGIN X509 CERTIFICATE-----
MIIBHDCBxaADAgECAgIcxzAJBgcqhkjOPQQBMBAxDjAMBgNVBAMUBVBLSVghMB4X
DTE0MDkxNDA2MTU1MFoXDTI0MDkxNDA2MTU1MFowEDEOMAwGA1UEAxQFUEtJWCEw
WTATBgcqhkjOPQIBBggqhkjOPQMBBwNCAATwoQSr863QrR0PoRIYQ96H7WykDePH
Wa0eVAE24bth43wCNc+U5aZ761dhGhSSJkVWRgVH5+prLIr+nzfIq+X4oxAwDjAM
BgNVHRMBAf8EAjAAMAkGByqGSM49BAEDRwAwRAIfMdKS5F63lMnWVhi7uaKJzKCs
NnY/OKgBex6MIEAv2AIhAI2GdvfL+mGvhyPZE+JxRxWChmggb5/9eHdUcmW/jkOH
-----END X509 CERTIFICATE-----
Figure 16: Non-standard 'X509' Certificate Example
-----BEGIN X.509 CERTIFICATE-----
MIIBHDCBxaADAgECAgIcxzAJBgcqhkjOPQQBMBAxDjAMBgNVBAMUBVBLSVghMB4X
DTE0MDkxNDA2MTU1MFoXDTI0MDkxNDA2MTU1MFowEDEOMAwGA1UEAxQFUEtJWCEw
WTATBgcqhkjOPQIBBggqhkjOPQMBBwNCAATwoQSr863QrR0PoRIYQ96H7WykDePH
Wa0eVAE24bth43wCNc+U5aZ761dhGhSSJkVWRgVH5+prLIr+nzfIq+X4oxAwDjAM
BgNVHRMBAf8EAjAAMAkGByqGSM49BAEDRwAwRAIfMdKS5F63lMnWVhi7uaKJzKCs
NnY/OKgBex6MIEAv2AIhAI2GdvfL+mGvhyPZE+JxRxWChmggb5/9eHdUcmW/jkOH
-----END X.509 CERTIFICATE-----
Figure 17: Non-standard 'X.509' Certificate Example
-----BEGIN NEW CERTIFICATE REQUEST-----
MIIBWDCCAQcCAQAwTjELMAkGA1UEBhMCU0UxJzAlBgNVBAoTHlNpbW9uIEpvc2Vm
c3NvbiBEYXRha29uc3VsdCBBQjEWMBQGA1UEAxMNam9zZWZzc29uLm9yZzBOMBAG
ByqGSM49AgEGBSuBBAAhAzoABLLPSkuXY0l66MbxVJ3Mot5FCFuqQfn6dTs+9/CM
EOlSwVej77tj56kj9R/j9Q+LfysX8FO9I5p3oGIwYAYJKoZIhvcNAQkOMVMwUTAY
BgNVHREEETAPgg1qb3NlZnNzb24ub3JnMAwGA1UdEwEB/wQCMAAwDwYDVR0PAQH/
BAUDAwegADAWBgNVHSUBAf8EDDAKBggrBgEFBQcDATAKBggqhkjOPQQDAgM/ADA8
AhxBvfhxPFfbBbsE1NoFmCUczOFApEuQVUw3ZP69AhwWXk3dgSUsKnuwL5g/ftAY
dEQc8B8jAcnuOrfU
-----END NEW CERTIFICATE REQUEST-----
Figure 18: Non-standard 'NEW' PKCS #10 Example
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-----BEGIN CERTIFICATE CHAIN-----
MIHjBgsqhkiG9w0BCRABF6CB0zCB0AIBADFho18CAQCgGwYJKoZIhvcNAQUMMA4E
CLfrI6dr0gUWAgITiDAjBgsqhkiG9w0BCRADCTAUBggqhkiG9w0DBwQIZpECRWtz
u5kEGDCjerXY8odQ7EEEromZJvAurk/j81IrozBSBgkqhkiG9w0BBwEwMwYLKoZI
hvcNAQkQAw8wJDAUBggqhkiG9w0DBwQI0tCBcU09nxEwDAYIKwYBBQUIAQIFAIAQ
OsYGYUFdAH0RNc1p4VbKEAQUM2Xo8PMHBoYdqEcsbTodlCFAZH4=
-----END CERTIFICATE CHAIN-----
Figure 19: Non-standard 'CERTIFICATE CHAIN' Example
Appendix B. DER Expectations
This appendix is informative. Consult the respective standards for
the normative rules.
DER is a restricted profile of BER [X.690]; thus, all DER encodings
of data values are BER encodings, but just one of the BER encodings
is the DER encoding for a data value. Canonical encoding matters
when performing cryptographic operations; additionally, canonical
encoding has certain efficiency advantages for parsers. There are
three principal reasons to encode with DER:
1. A digital signature is (supposed to be) computed over the DER
encoding of the semantic content, so providing anything other
than the DER encoding is senseless. (In practice, an implementer
might choose to have an implementation parse and digest the data
as is, but this practice amounts to guesswork.)
2. In practice, cryptographic hashes are computed over the DER
encoding for identification.
3. In practice, the content is small. DER always encodes data
values in definite-length form (where the length is stated at the
beginning of the encoding); thus, a parser can anticipate memory
or resource usage up front.
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Figure 20 matches the structures in this document with the particular
reasons for DER encoding:
Sec. Label Reasons
----+----------------------+-------
5 CERTIFICATE 1 2 ~3
6 X509 CRL 1
7 CERTIFICATE REQUEST 1 ~3
8 PKCS7 *
9 CMS *
10 PRIVATE KEY 3
11 ENCRYPTED PRIVATE KEY 3
12 ATTRIBUTE CERTIFICATE 1 ~3
13 PUBLIC KEY 2 3
Figure 20: Guide for DER Encoding
* Cryptographic Message Syntax is designed for content of any length;
indefinite-length encoding enables one-pass processing (streaming)
when generating the encoding. Only certain parts -- namely, signed
and authenticated attributes -- need to be DER encoded.
~ Although not always "small", these encoded structures should not be
particularly "large" (e.g., more than 16 kilobytes). The parser
ought to be informed of large things up front in any event; this is
yet another reason to DER encode these things in the first place.
Figure 20: Guide for DER Encoding
Acknowledgements
Peter Gutmann suggested to document labels for Attribute Certificates
and PKCS #7 messages, and to add examples for the non-standard
variants. Dr. Stephen Henson suggested distinguishing when BER
versus DER is appropriate or necessary.
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Authors' Addresses
Simon Josefsson
SJD AB
Johan Olof Wallins Vaeg 13
Solna 171 64
Sweden
EMail: simon@josefsson.org
URI: http://josefsson.org/
Sean Leonard
Penango, Inc.
5900 Wilshire Boulevard
21st Floor
Los Angeles, CA 90036
United States
EMail: dev+ietf@seantek.com
URI: http://www.penango.com/
Josefsson & Leonard Standards Track [Page 20]