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

The following 'Verified' errata have been incorporated in this document: EID 7229
Network Working Group                                   K. Zeilenga, Ed.
Request for Comments: 4514                           OpenLDAP Foundation
Obsoletes: 2253                                                June 2006
Category: Standards Track

             Lightweight Directory Access Protocol (LDAP):
              String Representation of Distinguished Names

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 (2006).


   The X.500 Directory uses distinguished names (DNs) as primary keys to
   entries in the directory.  This document defines the string
   representation used in the Lightweight Directory Access Protocol
   (LDAP) to transfer distinguished names.  The string representation is
   designed to give a clean representation of commonly used
   distinguished names, while being able to represent any distinguished

1.  Background and Intended Usage

   In X.500-based directory systems [X.500], including those accessed
   using the Lightweight Directory Access Protocol (LDAP) [RFC4510],
   distinguished names (DNs) are used to unambiguously refer to
   directory entries [X.501][RFC4512].

   The structure of a DN [X.501] is described in terms of ASN.1 [X.680].
   In the X.500 Directory Access Protocol [X.511] (and other ITU-defined
   directory protocols), DNs are encoded using the Basic Encoding Rules
   (BER) [X.690].  In LDAP, DNs are represented in the string form
   described in this document.

   It is important to have a common format to be able to unambiguously
   represent a distinguished name.  The primary goal of this
   specification is ease of encoding and decoding.  A secondary goal is
   to have names that are human readable.  It is not expected that LDAP

   implementations with a human user interface would display these
   strings directly to the user, but that they would most likely be
   performing translations (such as expressing attribute type names in
   the local national language).

   This document defines the string representation of Distinguished
   Names used in LDAP [RFC4511][RFC4517].  Section 2 details the
   RECOMMENDED algorithm for converting a DN from its ASN.1 structured
   representation to a string.  Section 3 details how to convert a DN
   from a string to an ASN.1 structured representation.

   While other documents may define other algorithms for converting a DN
   from its ASN.1 structured representation to a string, all algorithms
   MUST produce strings that adhere to the requirements of Section 3.

   This document does not define a canonical string representation for
   DNs.  Comparison of DNs for equality is to be performed in accordance
   with the distinguishedNameMatch matching rule [RFC4517].

   This document is a integral part of the LDAP technical specification
   [RFC4510], which obsoletes the previously defined LDAP technical
   specification, RFC 3377, in its entirety.  This document obsoletes
   RFC 2253.  Changes since RFC 2253 are summarized in Appendix B.

   This specification assumes familiarity with X.500 [X.500] and the
   concept of Distinguished Name [X.501][RFC4512].

1.1.  Conventions

   The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
   document are to be interpreted as described in BCP 14 [RFC2119].

   Character names in this document use the notation for code points and
   names from the Unicode Standard [Unicode].  For example, the letter
   "a" may be represented as either <U+0061> or <LATIN SMALL LETTER A>.

   Note: a glossary of terms used in Unicode can be found in [Glossary].
   Information on the Unicode character encoding model can be found in

2.  Converting DistinguishedName from ASN.1 to a String

   X.501 [X.501] defines the ASN.1 [X.680] structure of distinguished
   name.  The following is a variant provided for discussion purposes.

      DistinguishedName ::= RDNSequence

      RDNSequence ::= SEQUENCE OF RelativeDistinguishedName

      RelativeDistinguishedName ::= SET SIZE (1..MAX) OF

      AttributeTypeAndValue ::= SEQUENCE {
          type  AttributeType,
          value AttributeValue }

   This section defines the RECOMMENDED algorithm for converting a
   distinguished name from an ASN.1-structured representation to a UTF-8
   [RFC3629] encoded Unicode [Unicode] character string representation.
   Other documents may describe other algorithms for converting a
   distinguished name to a string, but only strings that conform to the
   grammar defined in Section 3 SHALL be produced by LDAP

2.1.  Converting the RDNSequence

   If the RDNSequence is an empty sequence, the result is the empty or
   zero-length string.

   Otherwise, the output consists of the string encodings of each
   RelativeDistinguishedName in the RDNSequence (according to Section
   2.2), starting with the last element of the sequence and moving
   backwards toward the first.

   The encodings of adjoining RelativeDistinguishedNames are separated
   by a comma (',' U+002C) character.

2.2.  Converting RelativeDistinguishedName

   When converting from an ASN.1 RelativeDistinguishedName to a string,
   the output consists of the string encodings of each
   AttributeTypeAndValue (according to Section 2.3), in any order.

   Where there is a multi-valued RDN, the outputs from adjoining
   AttributeTypeAndValues are separated by a plus sign ('+' U+002B)

2.3.  Converting AttributeTypeAndValue

   The AttributeTypeAndValue is encoded as the string representation of
   the AttributeType, followed by an equals sign ('=' U+003D) character,
   followed by the string representation of the AttributeValue.  The
   encoding of the AttributeValue is given in Section 2.4.

   If the AttributeType is defined to have a short name (descriptor)
   [RFC4512] and that short name is known to be registered [REGISTRY]
   [RFC4520] as identifying the AttributeType, that short name, a
   <descr>, is used.  Otherwise the AttributeType is encoded as the
   dotted-decimal encoding, a <numericoid>, of its OBJECT IDENTIFIER.
   The <descr> and <numericoid> are defined in [RFC4512].

   Implementations are not expected to dynamically update their
   knowledge of registered short names.  However, implementations SHOULD
   provide a mechanism to allow their knowledge of registered short
   names to be updated.

2.4.  Converting an AttributeValue from ASN.1 to a String

   If the AttributeType is of the dotted-decimal form, the
      AttributeValue is represented by a number sign ('#' U+0023) 
EID 7229 (Verified) is as follows:

Section: 2.4

Original Text:

   AttributeValue is represented by an number sign ('#' U+0023)

Corrected Text:

   AttributeValue is represented by a number sign ('#' U+0023)
Wrong form of the indefinite article.
character followed by the hexadecimal encoding of each of the octets of the BER encoding of the X.500 AttributeValue. This form is also used when the syntax of the AttributeValue does not have an LDAP- specific ([RFC4517], Section 3.1) string encoding defined for it, or the LDAP-specific string encoding is not restricted to UTF-8-encoded Unicode characters. This form may also be used in other cases, such as when a reversible string representation is desired (see Section 5.2). Otherwise, if the AttributeValue is of a syntax that has a LDAP- specific string encoding, the value is converted first to a UTF-8- encoded Unicode string according to its syntax specification (see [RFC4517], Section 3.3, for examples). If that UTF-8-encoded Unicode string does not have any of the following characters that need escaping, then that string can be used as the string representation of the value. - a space (' ' U+0020) or number sign ('#' U+0023) occurring at the beginning of the string; - a space (' ' U+0020) character occurring at the end of the string; - one of the characters '"', '+', ',', ';', '<', '>', or '\' (U+0022, U+002B, U+002C, U+003B, U+003C, U+003E, or U+005C, respectively); - the null (U+0000) character. Other characters may be escaped. Each octet of the character to be escaped is replaced by a backslash and two hex digits, which form a single octet in the code of the character. Alternatively, if and only if the character to be escaped is one of ' ', '"', '#', '+', ',', ';', '<', '=', '>', or '\' (U+0020, U+0022, U+0023, U+002B, U+002C, U+003B, U+003C, U+003D, U+003E, U+005C, respectively) it can be prefixed by a backslash ('\' U+005C). Examples of the escaping mechanism are shown in Section 4. 3. Parsing a String Back to a Distinguished Name The string representation of Distinguished Names is restricted to UTF-8 [RFC3629] encoded Unicode [Unicode] characters. The structure of this string representation is specified using the following Augmented BNF [RFC4234] grammar: distinguishedName = [ relativeDistinguishedName *( COMMA relativeDistinguishedName ) ] relativeDistinguishedName = attributeTypeAndValue *( PLUS attributeTypeAndValue ) attributeTypeAndValue = attributeType EQUALS attributeValue attributeType = descr / numericoid attributeValue = string / hexstring ; The following characters are to be escaped when they appear ; in the value to be encoded: ESC, one of <escaped>, leading ; SHARP or SPACE, trailing SPACE, and NULL. string = [ ( leadchar / pair ) [ *( stringchar / pair ) ( trailchar / pair ) ] ] leadchar = LUTF1 / UTFMB LUTF1 = %x01-1F / %x21 / %x24-2A / %x2D-3A / %x3D / %x3F-5B / %x5D-7F trailchar = TUTF1 / UTFMB TUTF1 = %x01-1F / %x21 / %x23-2A / %x2D-3A / %x3D / %x3F-5B / %x5D-7F stringchar = SUTF1 / UTFMB SUTF1 = %x01-21 / %x23-2A / %x2D-3A / %x3D / %x3F-5B / %x5D-7F pair = ESC ( ESC / special / hexpair ) special = escaped / SPACE / SHARP / EQUALS escaped = DQUOTE / PLUS / COMMA / SEMI / LANGLE / RANGLE hexstring = SHARP 1*hexpair hexpair = HEX HEX where the productions <descr>, <numericoid>, <COMMA>, <DQUOTE>, <EQUALS>, <ESC>, <HEX>, <LANGLE>, <NULL>, <PLUS>, <RANGLE>, <SEMI>, <SPACE>, <SHARP>, and <UTFMB> are defined in [RFC4512]. Each <attributeType>, either a <descr> or a <numericoid>, refers to an attribute type of an attribute value assertion (AVA). The <attributeType> is followed by an <EQUALS> and an <attributeValue>. The <attributeValue> is either in <string> or <hexstring> form. If in <string> form, a LDAP string representation asserted value can be obtained by replacing (left to right, non-recursively) each <pair> appearing in the <string> as follows: replace <ESC><ESC> with <ESC>; replace <ESC><special> with <special>; replace <ESC><hexpair> with the octet indicated by the <hexpair>. If in <hexstring> form, a BER representation can be obtained from converting each <hexpair> of the <hexstring> to the octet indicated by the <hexpair>. There is one or more attribute value assertions, separated by <PLUS>, for a relative distinguished name. There is zero or more relative distinguished names, separated by <COMMA>, for a distinguished name. Implementations MUST recognize AttributeType name strings (descriptors) listed in the following table, but MAY recognize other name strings. String X.500 AttributeType ------ -------------------------------------------- CN commonName ( L localityName ( ST stateOrProvinceName ( O organizationName ( OU organizationalUnitName ( C countryName ( STREET streetAddress ( DC domainComponent (0.9.2342.19200300.100.1.25) UID userId (0.9.2342.19200300.100.1.1) These attribute types are described in [RFC4519]. Implementations MAY recognize other DN string representations. However, as there is no requirement that alternative DN string representations be recognized (and, if so, how), implementations SHOULD only generate DN strings in accordance with Section 2 of this document. 4. Examples This notation is designed to be convenient for common forms of name. This section gives a few examples of distinguished names written using this notation. First is a name containing three relative distinguished names (RDNs): UID=jsmith,DC=example,DC=net Here is an example of a name containing three RDNs, in which the first RDN is multi-valued: OU=Sales+CN=J. Smith,DC=example,DC=net This example shows the method of escaping of a special characters appearing in a common name: CN=James \"Jim\" Smith\, III,DC=example,DC=net The following shows the method for encoding a value that contains a carriage return character: CN=Before\0dAfter,DC=example,DC=net In this RDN example, the type in the RDN is unrecognized, and the value is the BER encoding of an OCTET STRING containing two octets, 0x48 and 0x69. Finally, this example shows an RDN whose commonName value consists of 5 letters: Unicode Character Code UTF-8 Escaped ------------------------------- ------ ------ -------- LATIN CAPITAL LETTER L U+004C 0x4C L LATIN SMALL LETTER U U+0075 0x75 u LATIN SMALL LETTER C WITH CARON U+010D 0xC48D \C4\8D LATIN SMALL LETTER I U+0069 0x69 i LATIN SMALL LETTER C WITH ACUTE U+0107 0xC487 \C4\87 This could be encoded in printable ASCII [ASCII] (useful for debugging purposes) as: CN=Lu\C4\8Di\C4\87 5. Security Considerations The following security considerations are specific to the handling of distinguished names. LDAP security considerations are discussed in [RFC4511] and other documents comprising the LDAP Technical Specification [RFC4510]. 5.1. Disclosure Distinguished Names typically consist of descriptive information about the entries they name, which can be people, organizations, devices, or other real-world objects. This frequently includes some of the following kinds of information: - the common name of the object (i.e., a person's full name) - an email or TCP/IP address - its physical location (country, locality, city, street address) - organizational attributes (such as department name or affiliation) In some cases, such information can be considered sensitive. In many countries, privacy laws exist that prohibit disclosure of certain kinds of descriptive information (e.g., email addresses). Hence, server implementers are encouraged to support Directory Information Tree (DIT) structural rules and name forms [RFC4512], as these provide a mechanism for administrators to select appropriate naming attributes for entries. Administrators are encouraged to use mechanisms, access controls, and other administrative controls that may be available to restrict use of attributes containing sensitive information in naming of entries. Additionally, use of authentication and data security services in LDAP [RFC4513][RFC4511] should be considered. 5.2. Use of Distinguished Names in Security Applications The transformations of an AttributeValue value from its X.501 form to an LDAP string representation are not always reversible back to the same BER (Basic Encoding Rules) or DER (Distinguished Encoding Rules) form. An example of a situation that requires the DER form of a distinguished name is the verification of an X.509 certificate. For example, a distinguished name consisting of one RDN with one AVA, in which the type is commonName and the value is of the TeletexString choice with the letters 'Sam', would be represented in LDAP as the string <CN=Sam>. Another distinguished name in which the value is still 'Sam', but is of the PrintableString choice, would have the same representation <CN=Sam>. Applications that require the reconstruction of the DER form of the value SHOULD NOT use the string representation of attribute syntaxes when converting a distinguished name to the LDAP format. Instead, they SHOULD use the hexadecimal form prefixed by the number sign ('#' U+0023) as described in the first paragraph of Section 2.4. 6. Acknowledgements This document is an update to RFC 2253, by Mark Wahl, Tim Howes, and Steve Kille. RFC 2253 was a product of the IETF ASID Working Group. This document is a product of the IETF LDAPBIS Working Group. 7. References 7.1. Normative References [REGISTRY] IANA, Object Identifier Descriptors Registry, <>. [Unicode] The Unicode Consortium, "The Unicode Standard, Version 3.2.0" is defined by "The Unicode Standard, Version 3.0" (Reading, MA, Addison-Wesley, 2000. ISBN 0-201- 61633-5), as amended by the "Unicode Standard Annex #27: Unicode 3.1" ( and by the "Unicode Standard Annex #28: Unicode 3.2" ( [X.501] International Telecommunication Union - Telecommunication Standardization Sector, "The Directory -- Models," X.501(1993) (also ISO/IEC 9594- 2:1994). [X.680] International Telecommunication Union - Telecommunication Standardization Sector, "Abstract Syntax Notation One (ASN.1) - Specification of Basic Notation", X.680(1997) (also ISO/IEC 8824-1:1998). [RFC2119] Bradner, S., "Key words for use in RFCs to Indicate Requirement Levels", BCP 14, RFC 2119, March 1997. [RFC3629] Yergeau, F., "UTF-8, a transformation format of ISO 10646", STD 63, RFC 3629, November 2003. [RFC4234] Crocker, D. and P. Overell, "Augmented BNF for Syntax Specifications: ABNF", RFC 4234, October 2005. [RFC4510] Zeilenga, K., Ed., "Lightweight Directory Access Protocol (LDAP): Technical Specification Road Map", RFC 4510, June 2006. [RFC4511] Sermersheim, J., Ed., "Lightweight Directory Access Protocol (LDAP): The Protocol", RFC 4511, June 2006. [RFC4512] Zeilenga, K., "Lightweight Directory Access Protocol (LDAP): Directory Information Models", RFC 4512, June 2006. [RFC4513] Harrison, R., Ed., "Lightweight Directory Access Protocol (LDAP): Authentication Methods and Security Mechanisms", RFC 4513, June 2006. [RFC4517] Legg, S., Ed., "Lightweight Directory Access Protocol (LDAP): Syntaxes and Matching Rules", RFC 4517, June 2006. [RFC4519] Sciberras, A., Ed., "Lightweight Directory Access Protocol (LDAP): Schema for User Applications", RFC 4519, June 2006. [RFC4520] Zeilenga, K., "Internet Assigned Numbers Authority (IANA) Considerations for the Lightweight Directory Access Protocol (LDAP)", BCP 64, RFC 4520, June 2006. 7.2. Informative References [ASCII] Coded Character Set--7-bit American Standard Code for Information Interchange, ANSI X3.4-1986. [CharModel] Whistler, K. and M. Davis, "Unicode Technical Report #17, Character Encoding Model", UTR17, <>, August 2000. [Glossary] The Unicode Consortium, "Unicode Glossary", <>. [X.500] International Telecommunication Union - Telecommunication Standardization Sector, "The Directory -- Overview of concepts, models and services," X.500(1993) (also ISO/IEC 9594-1:1994). [X.511] International Telecommunication Union - Telecommunication Standardization Sector, "The Directory: Abstract Service Definition", X.511(1993) (also ISO/IEC 9594-3:1993). [X.690] International Telecommunication Union - Telecommunication Standardization Sector, "Specification of ASN.1 encoding rules: Basic Encoding Rules (BER), Canonical Encoding Rules (CER), and Distinguished Encoding Rules (DER)", X.690(1997) (also ISO/IEC 8825-1:1998). [RFC2849] Good, G., "The LDAP Data Interchange Format (LDIF) - Technical Specification", RFC 2849, June 2000. Appendix A. Presentation Issues This appendix is provided for informational purposes only; it is not a normative part of this specification. The string representation described in this document is not intended to be presented to humans without translation. However, at times it may be desirable to present non-translated DN strings to users. This section discusses presentation issues associated with non-translated DN strings. Issues with presentation of translated DN strings are not discussed in this appendix. Transcoding issues are also not discussed in this appendix. This appendix provides guidance for applications presenting DN strings to users. This section is not comprehensive; it does not discuss all presentation issues that implementers may face. Not all user interfaces are capable of displaying the full set of Unicode characters. Some Unicode characters are not displayable. It is recommended that human interfaces use the optional hex pair escaping mechanism (Section 2.3) to produce a string representation suitable for display to the user. For example, an application can generate a DN string for display that escapes all non-printable characters appearing in the AttributeValue's string representation (as demonstrated in the final example of Section 4). When a DN string is displayed in free-form text, it is often necessary to distinguish the DN string from surrounding text. While this is often done with whitespace (as demonstrated in Section 4), it is noted that DN strings may end with whitespace. Careful readers of Section 3 will note that the characters '<' (U+003C) and '>' (U+003E) may only appear in the DN string if escaped. These characters are intended to be used in free-form text to distinguish a DN string from surrounding text. For example, <CN=Sam\ > distinguishes the string representation of the DN composed of one RDN consisting of the AVA (the commonName (CN) value 'Sam ') from the surrounding text. It should be noted to the user that the wrapping '<' and '>' characters are not part of the DN string. DN strings can be quite long. It is often desirable to line-wrap overly long DN strings in presentations. Line wrapping should be done by inserting whitespace after the RDN separator character or, if necessary, after the AVA separator character. It should be noted to the user that the inserted whitespace is not part of the DN string and is to be removed before use in LDAP. For example, the following DN string is long: CN=Kurt D. Zeilenga,OU=Engineering,L=Redwood Shores, O=OpenLDAP Foundation,ST=California,C=US So it has been line-wrapped for readability. The extra whitespace is to be removed before the DN string is used in LDAP. Inserting whitespace is not advised because it may not be obvious to the user which whitespace is part of the DN string and which whitespace was added for readability. Another alternative is to use the LDAP Data Interchange Format (LDIF) [RFC2849]. For example: # This entry has a long DN... dn: CN=Kurt D. Zeilenga,OU=Engineering,L=Redwood Shores, O=OpenLDAP Foundation,ST=California,C=US CN: Kurt D. Zeilenga SN: Zeilenga objectClass: person Appendix B. Changes Made since RFC 2253 This appendix is provided for informational purposes only, it is not a normative part of this specification. The following substantive changes were made to RFC 2253: - Removed IESG Note. The IESG Note has been addressed. - Replaced all references to ISO 10646-1 with [Unicode]. - Clarified (in Section 1) that this document does not define a canonical string representation. - Clarified that Section 2 describes the RECOMMENDED encoding algorithm and that alternative algorithms are allowed. Some encoding options described in RFC 2253 are now treated as alternative algorithms in this specification. - Revised specification (in Section 2) to allow short names of any registered attribute type to appear in string representations of DNs instead of being restricted to a "published table". Removed "as an example" language. Added statement (in Section 3) allowing recognition of additional names but require recognition of those names in the published table. The table now appears in Section 3. - Removed specification of additional requirements for LDAPv2 implementations which also support LDAPv3 (RFC 2253, Section 4) as LDAPv2 is now Historic. - Allowed recognition of alternative string representations. - Updated Section 2.4 to allow hex pair escaping of all characters and clarified escaping for when multiple octet UTF-8 encodings are present. Indicated that null (U+0000) character is to be escaped. Indicated that equals sign ('=' U+003D) character may be escaped as '\='. - Rewrote Section 3 to use ABNF as defined in RFC 4234. - Updated the Section 3 ABNF. Changes include: + allowed AttributeType short names of length 1 (e.g., 'L'), + used more restrictive <oid> production in AttributeTypes, + did not require escaping of equals sign ('=' U+003D) characters, + did not require escaping of non-leading number sign ('#' U+0023) characters, + allowed space (' ' U+0020) to be escaped as '\ ', + required hex escaping of null (U+0000) characters, and + removed LDAPv2-only constructs. - Updated Section 3 to describe how to parse elements of the grammar. - Rewrote examples. - Added reference to documentations containing general LDAP security considerations. - Added discussion of presentation issues (Appendix A). - Added this appendix. In addition, numerous editorial changes were made. Editor's Address Kurt D. Zeilenga OpenLDAP Foundation EMail: Full Copyright Statement Copyright (C) The Internet Society (2006). This document is subject to the rights, licenses and restrictions contained in BCP 78, and except as set forth therein, the authors retain all their rights. This document and the information contained herein are provided on an "AS IS" basis and THE CONTRIBUTOR, THE ORGANIZATION HE/SHE REPRESENTS OR IS SPONSORED BY (IF ANY), THE INTERNET SOCIETY AND THE INTERNET ENGINEERING TASK FORCE DISCLAIM ALL WARRANTIES, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO ANY WARRANTY THAT THE USE OF THE INFORMATION HEREIN WILL NOT INFRINGE ANY RIGHTS OR ANY IMPLIED WARRANTIES OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE. 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