- Core LDAP Specification
- RFC-4510 Lightweight Directory Access Protocol (LDAP): Technical Specification Road Map
- RFC-4511 Lightweight Directory Access Protocol (LDAP): The Protocol
- RFC-4512 Lightweight Directory Access Protocol (LDAP): Directory Information Models
- RFC-4513 Lightweight Directory Access Protocol (LDAP): Authentication Methods and Security Mechanisms
- RFC-4514 Lightweight Directory Access Protocol (LDAP): String Representation of Distinguished Names
- RFC-4515 Lightweight Directory Access Protocol (LDAP): String Representation of Search Filters
- RFC-4516 Lightweight Directory Access Protocol (LDAP): Uniform Resource Locator
- RFC-4517 Lightweight Directory Access Protocol (LDAP): Syntaxes and Matching Rules
- RFC-4518 Lightweight Directory Access Protocol (LDAP): Internationalized String Preparation
- RFC-4519 Lightweight Directory Access Protocol (LDAP): Schema for User Applications
- Other LDAP Related RFCs - Proposed Standards
- RFC-6171 The Lightweight Directory Access Protocol (LDAP) Don't Use Copy Control
- RFC-5020 The Lightweight Directory Access Protocol (LDAP) entryDN Operational Attribute
- RFC-4792 Encoding Instructions for the Generic String Encoding Rules (GSER)
- RFC-4532 Lightweight Directory Access Protocol (LDAP) Who am I? Operation
- RFC-4530 Lightweight Directory Access Protocol (LDAP) entryUUID Operational Attribute
- RFC-4528 Lightweight Directory Access Protocol (LDAP) Assertion Control
- RFC-4527 Lightweight Directory Access Protocol (LDAP) Read Entry Controls
- RFC-4526 Lightweight Directory Access Protocol (LDAP) Absolute True and False Filters
- RFC-4524 COSINE LDAP/X.500 Schema
- RFC-4523 Lightweight Directory Access Protocol (LDAP) Schema Definitions for X.509 Certificates
- RFC-4522 Lightweight Directory Access Protocol (LDAP): The Binary Encoding Option
- RFC-4370 Lightweight Directory Access Protocol (LDAP) Proxied Authorization Control
- RFC-4104 Policy Core Extension Lightweight Directory Access Protocol Schema (PCELS)
- RFC-3928 Lightweight Directory Access Protocol (LDAP) Client Update Protocol (LCUP)
- RFC-3909 Lightweight Directory Access Protocol (LDAP) Cancel Operation
- RFC-3876 Returning Matched Values with the Lightweight Directory Access Protocol version 3 (LDAPv3)
- RFC-3866 Language Tags and Ranges in the Lightweight Directory Access Protocol (LDAP)
- RFC-3727 ASN.1 Module Definition for the LDAP and X.500 Component Matching Rules
- RFC-3703 Policy Core Lightweight Directory Access Protocol (LDAP) Schema
- RFC-3698 Lightweight Directory Access Protocol (LDAP): Additional Matching Rules
- RFC-3687 Lightweight Directory Access Protocol (LDAP) and X.500 Component Matching Rules
- RFC-3672 Subentries in the Lightweight Directory Access Protocol (LDAP)
- RFC-3671 Collective Attributes in the Lightweight Directory Access Protocol (LDAP)
- RFC-3296 Named Subordinate References in Lightweight Directory Access Protocol (LDAP) Directories
- RFC-3062 LDAP Password Modify Extended Operation
- RFC-2891 LDAP Control Extension for Server Side Sorting of Search Results
- RFC-2849 The LDAP Data Interchange Format (LDIF) - Technical Specification
- RFC-2831 Using Digest Authentication as a SASL Mechanism
- RFC-2739 Calendar Attributes for vCard and LDAP
- RFC-2589 Extensions for Dynamic Directory Services
- RFC-2559 Internet X.509 Public Key Infrastructure Operational Protocols - LDAPv2
- RFC-2247 Using Domains in LDAP/X.500 Distinguished Names
- RFC-2222 Simple Authentication and Security Layer (SASL)
- RFC-2218 A Common Schema for the Internet White Pages Service
- RFC-2164 Use of an X.500/LDAP directory to support MIXER address mapping
- RFC-2079 Definition of an X.500 Attribute Type and an Object Class to Hold Uniform Resource Identifiers
- Other LDAP Related RFCs - Best Current Practice
- Other LDAP Related RFCs - Informational
- RFC-5803 Lightweight Directory Access Protocol (LDAP) Schema for Storing Salted Challenge Response Authentication Mechanism (SCRAM) Secrets
- RFC-4876 A Configuration Profile Schema for Lightweight Directory Access Protocol (LDAP)-Based Agents
- RFC-4529 Requesting Attributes by Object Class in the Lightweight Directory Access Protocol (LDAP)
- RFC-4525 Lightweight Directory Access Protocol (LDAP) Modify-Increment Extension
- RFC-4403 Lightweight Directory Access Protocol (LDAP) Schema for Universal Description, Discovery, and Integration version 3 (UDDIv3)
- RFC-4373 Lightweight Directory Access Protocol (LDAP) Bulk Update/Replication Protocol (LBURP)
- RFC-3944 H.350 Directory Services
- RFC-3829 Lightweight Directory Access Protocol (LDAP) Authorization Identity Request and Response Controls
- RFC-3712 Lightweight Directory Access Protocol (LDAP): Schema for Printer Services
- RFC-3494 Lightweight Directory Access Protocol version 2 (LDAPv2) to Historic Status
- RFC-3384 Lightweight Directory Access Protocol (version 3) Replication Requirements
- RFC-3112 LDAP Authentication Password Schema
- RFC-3045 Storing Vendor Information in the LDAP root DSE
- RFC-2985 PKCS #9: Selected Object Classes and Attribute Types Version 2.0
- RFC-2967 TISDAG - Technical Infrastructure for Swedish Directory Access Gateways
- RFC-2927 MIME Directory Profile for LDAP Schema
- RFC-2926 Conversion of LDAP Schemas to and from SLP Templates
- RFC-2820 Access Control Requirements for LDAP
- RFC-2798 Definition of the inetOrgPerson Object Class
- RFC-2714 Schema for Representing CORBA Objects in an LDAP Directory
- RFC-2713 Schema for Representing Java Objects in an LDAP Directory
- RFC-2696 LDAP Control Extension for Simple Paged Results Manipulation
- RFC-1823 The LDAP Application Program Interface
- Other LDAP Related RFCs - Experimental
- RFC-5805 Lightweight Directory Access Protocol (LDAP) Transactions
- RFC-4533 The Lightweight Directory Access Protocol (LDAP) Content Synchronization Operation
- RFC-4531 Lightweight Directory Access Protocol (LDAP) Turn Operation
- RFC-3663 Domain Administrative Data in Lightweight Directory Access Protocol (LDAP)
- RFC-3088 OpenLDAP Root Service - An experimental LDAP referral service
- RFC-2657 LDAPv2 Client vs. the Index Mesh
- RFC-2649 Signed Directory Operations Using S/MIME
- RFC-2307 An Approach for Using LDAP as a Network Information Service
- Expired but still interesting Internet Drafts
- draft-wahl-ldap-adminaddr -- Administrator Address Attribute
- draft-zeilenga-ldap-noop -- The LDAP No-Op Control
- draft-legg-ldap-transfer -- Lightweight Directory Access Protocol (LDAP): Transfer Encoding Options
- draft-furuseth-ldap-untypedobject -- Structural object class 'namedObject' for LDAP/X.500
- draft-wahl-ldap-p3p -- P3P Policy Attributes for LDAP
- draft-chu-ldap-xordered -- Ordered Entries and Values in LDAP
- draft-chu-ldap-logschema -- A Schema for Logging the LDAP Protocol
- draft-zeilenga-ldap-relax -- The LDAP Relax Rules Control
- draft-gpaterno-dhcp-ldap -- DHCP Option for LDAP Directory Services discovery
- draft-schleiff-ldap-xri -- LDAP Schema for eXtensible Resource Identifier (XRI)
- draft-wahl-ldap-session -- LDAP Session Tracking Control
- draft-wahl-ldap-subtree-source -- LDAP Subtree Data Source URI Attribute
- draft-ietf-ldapext-psearch -- Persistent Search: A Simple LDAP Change Notification Mechanism
- draft-ietf-ldapext-ldapv3-vlv -- LDAP Extensions for Scrolling View Browsing of Search Results
- Where to find the latest information
Net::LDAP::RFC - List of related RFC's
The LDAP protocol is defined in the following RFC's
The Lightweight Directory Access Protocol (LDAP) is an Internet protocol for accessing distributed directory services that act in accordance with X.500 data and service models. This document provides a road map of the LDAP Technical Specification.
This document describes the protocol elements, along with their semantics and encodings, of the Lightweight Directory Access Protocol (LDAP). LDAP provides access to distributed directory services that act in accordance with X.500 data and service models. These protocol elements are based on those described in the X.500 Directory Access Protocol (DAP).
The Lightweight Directory Access Protocol (LDAP) is an Internet protocol for accessing distributed directory services that act in accordance with X.500 data and service models. This document describes the X.500 Directory Information Models, as used in LDAP.
RFC-4513 Lightweight Directory Access Protocol (LDAP): Authentication Methods and Security Mechanisms
This document describes authentication methods and security mechanisms of the Lightweight Directory Access Protocol (LDAP). This document details establishment of Transport Layer Security (TLS) using the StartTLS operation.
This document details the simple Bind authentication method including anonymous, unauthenticated, and name/password mechanisms and the Simple Authentication and Security Layer (SASL) Bind authentication method including the EXTERNAL mechanism.
This document discusses various authentication and authorization states through which a session to an LDAP server may pass and the actions that trigger these state changes.
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 name.
Lightweight Directory Access Protocol (LDAP) search filters are transmitted in the LDAP protocol using a binary representation that is appropriate for use on the network. This document defines a human-readable string representation of LDAP search filters that is appropriate for use in LDAP URLs (RFC 4516) and in other applications.
This document describes a format for a Lightweight Directory Access Protocol (LDAP) Uniform Resource Locator (URL). An LDAP URL describes an LDAP search operation that is used to retrieve information from an LDAP directory, or, in the context of an LDAP referral or reference, an LDAP URL describes a service where an LDAP operation may be progressed.
Each attribute stored in a Lightweight Directory Access Protocol (LDAP) directory, whose values may be transferred in the LDAP protocol, has a defined syntax that constrains the structure and format of its values. The comparison semantics for values of a syntax are not part of the syntax definition but are instead provided through separately defined matching rules. Matching rules specify an argument, an assertion value, which also has a defined syntax. This document defines a base set of syntaxes and matching rules for use in defining attributes for LDAP directories.
The previous Lightweight Directory Access Protocol (LDAP) technical specifications did not precisely define how character string matching is to be performed. This led to a number of usability and interoperability problems. This document defines string preparation algorithms for character-based matching rules defined for use in LDAP.
This document is an integral part of the Lightweight Directory Access Protocol (LDAP) technical specification. It provides a technical specification of attribute types and object classes intended for use by LDAP directory clients for many directory services, such as White Pages. These objects are widely used as a basis for the schema in many LDAP directories. This document does not cover attributes used for the administration of directory servers, nor does it include directory objects defined for specific uses in other documents.
This document defines the Lightweight Directory Access Protocol (LDAP) Don't Use Copy control extension which allows a client to specify that copied information should not be used in providing service. This control is based upon the X.511 dontUseCopy service control option.
This document describes the LDAP/X.500 'entryDN' operational attribute. The attribute provides a copy of the entry's distinguished name for use in attribute value assertions.
Abstract Syntax Notation One (ASN.1) defines a general framework for annotating types in an ASN.1 specification with encoding instructions that alter how values of those types are encoded according to ASN.1 encoding rules. This document defines the supporting notation for encoding instructions that apply to the Generic String Encoding Rules (GSER), and in particular defines an encoding instruction to provide a machine-processable representation for the declaration of a GSER ChoiceOfStrings type.
This specification provides a mechanism for Lightweight Directory Access Protocol (LDAP) clients to obtain the authorization identity the server has associated with the user or application entity. This mechanism is specified as an LDAP extended operation called the LDAP "Who am I?" operation.
This document describes the LDAP/X.500 'entryUUID' operational attribute and associated matching rules and syntax. The attribute holds a server-assigned Universally Unique Identifier (UUID) for the object. Directory clients may use this attribute to distinguish objects identified by a distinguished name or to locate an object after renaming.
This document defines the Lightweight Directory Access Protocol (LDAP) Assertion Control, which allows a client to specify that a directory operation should only be processed if an assertion applied to the target entry of the operation is true. It can be used to construct "test and set", "test and clear", and other conditional operations.
This document specifies an extension to the Lightweight Directory Access Protocol (LDAP) to allow the client to read the target entry of an update operation. The client may request to read the entry before and/or after the modifications are applied. These reads are done as an atomic part of the update operation.
This document extends the Lightweight Directory Access Protocol (LDAP) to support absolute True and False filters based upon similar capabilities found in X.500 directory systems. The document also extends the String Representation of LDAP Search Filters to support these filters.
This document provides a collection of schema elements for use with the Lightweight Directory Access Protocol (LDAP) from the COSINE and Internet X.500 pilot projects.
This document describes schema for representing X.509 certificates, X.521 security information, and related elements in directories accessible using the Lightweight Directory Access Protocol (LDAP). The LDAP definitions for these X.509 and X.521 schema elements replace those provided in RFCs 2252 and 2256.
Each attribute stored in a Lightweight Directory Access Protocol (LDAP) directory has a defined syntax (i.e., data type). A syntax definition specifies how attribute values conforming to the syntax are normally represented when transferred in LDAP operations. This representation is referred to as the LDAP-specific encoding to distinguish it from other methods of encoding attribute values. This document defines an attribute option, the binary option, that can be used to specify that the associated attribute values are instead encoded according to the Basic Encoding Rules (BER) used by X.500 directories.
This document defines the Lightweight Directory Access Protocol (LDAP) Proxy Authorization Control. The Proxy Authorization Control allows a client to request that an operation be processed under a provided authorization identity instead of under the current authorization identity associated with the connection.
This document defines a number of changes and extensions to the Policy Core Lightweight Directory Access Protocol (LDAP) Schema (RFC 3703) based on the model extensions defined by the Policy Core Information Model (PCIM) Extensions (RFC 3460). These changes and extensions consist of new LDAP object classes and attribute types. Some of the schema items defined in this document re-implement existing concepts in accordance with their new semantics introduced by RFC 3460. The other schema items implement new concepts, not covered by RFC 3703. This document updates RFC 3703.
This document defines the Lightweight Directory Access Protocol (LDAP) Client Update Protocol (LCUP). The protocol is intended to allow an LDAP client to synchronize with the content of a directory information tree (DIT) stored by an LDAP server and to be notified about the changes to that content.
This specification describes a Lightweight Directory Access Protocol (LDAP) extended operation to cancel (or abandon) an outstanding operation. Unlike the LDAP Abandon operation, but like the X.511 Directory Access Protocol (DAP) Abandon operation, this operation has a response which provides an indication of its outcome.
This document describes a control for the Lightweight Directory Access Protocol version 3 that is used to return a subset of attribute values from an entry. Specifically, only those values that match a "values return" filter. Without support for this control, a client must retrieve all of an attribute's values and search for specific values locally.
It is often desirable to be able to indicate the natural language associated with values held in a directory and to be able to query the directory for values which fulfill the user's language needs. This document details the use of Language Tags and Ranges in the Lightweight Directory Access Protocol (LDAP).
This document updates the specification of the component matching rules for Lightweight Directory Access Protocol (LDAP) and X.500 directories (RFC3687) by collecting the Abstract Syntax Notation One (ASN.1) definitions of the component matching rules into an appropriately identified ASN.1 module so that other specifications may reference the component matching rule definitions from within their own ASN.1 modules.
This document defines a mapping of the Policy Core Information Model to a form that can be implemented in a directory that uses Lightweight Directory Access Protocol (LDAP) as its access protocol. This model defines two hierarchies of object classes: structural classes representing information for representing and controlling policy data as specified in RFC 3060, and relationship classes that indicate how instances of the structural classes are related to each other. Classes are also added to the LDAP schema to improve the performance of a client's interactions with an LDAP server when the client is retrieving large amounts of policy-related information. These classes exist only to optimize LDAP retrievals: there are no classes in the information model that correspond to them.
This document provides a collection of matching rules for use with the Lightweight Directory Access Protocol (LDAP). As these matching rules are simple adaptations of matching rules specified for use with the X.500 Directory, most are already in wide use.
The syntaxes of attributes in a Lightweight Directory Access Protocol (LDAP) or X.500 directory range from simple data types, such as text string, integer, or boolean, to complex structured data types, such as the syntaxes of the directory schema operational attributes. Matching rules defined for the complex syntaxes usually only provide the most immediately useful matching capability. This document defines generic matching rules that can match any user selected component parts in an attribute value of any arbitrarily complex attribute syntax.
In X.500 directories, subentries are special entries used to hold information associated with a subtree or subtree refinement. This document adapts X.500 subentries mechanisms for use with the Lightweight Directory Access Protocol (LDAP).
X.500 collective attributes allow common characteristics to be shared between collections of entries. This document summarizes the X.500 information model for collective attributes and describes use of collective attributes in LDAP (Lightweight Directory Access Protocol). This document provides schema definitions for collective attributes for use in LDAP.
This document details schema and protocol elements for representing and managing named subordinate references in Lightweight Directory Access Protocol (LDAP) Directories.
The integration of the Lightweight Directory Access Protocol (LDAP) and external authentication services has introduced non-DN authentication identities and allowed for non-directory storage of passwords. As such, mechanisms which update the directory (e.g., Modify) cannot be used to change a user's password. This document describes an LDAP extended operation to allow modification of user passwords which is not dependent upon the form of the authentication identity nor the password storage mechanism used.
This document describes two LDAPv3 control extensions for server side sorting of search results. These controls allows a client to specify the attribute types and matching rules a server should use when returning the results to an LDAP search request. The controls may be useful when the LDAP client has limited functionality or for some other reason cannot sort the results but still needs them sorted. Other permissible controls on search operations are not defined in this extension.
This document describes a file format suitable for describing directory information or modifications made to directory information. The file format, known as LDIF, for LDAP Data Interchange Format, is typically used to import and export directory information between LDAP-based directory servers, or to describe a set of changes which are to be applied to a directory.
This specification defines how HTTP Digest Authentication can be used as a SASL [RFC 2222] mechanism for any protocol that has a SASL profile. It is intended both as an improvement over CRAM-MD5 [RFC 2195] and as a convenient way to support a single authentication mechanism for web, mail, LDAP, and other protocols.
When scheduling a calendar entity, such as an event, it is a prerequisite that an organizer has the calendar address of each attendee that will be invited to the event. Additionally, access to an attendee's current "busy time" provides an a priori indication of whether the attendee will be free to participate in the event. In order to meet these challenges, a calendar user agent (CUA) needs a mechanism to locate individual user's calendar and free/busy time. This memo defines three mechanisms for obtaining a URI to a user's calendar and free/busy time. These include:
LDAP supports lightweight access to static directory services, allowing relatively fast search and update access. Static directory services store information about people that persists in its accuracy and value over a long period of time. Dynamic directory services are different in that they store information about people that only persists in its accuracy and value while people are online. Though the protocol operations and attributes used by dynamic directory services are similar to the ones used for static directory services, clients that are bound to a dynamic directory service need to periodically refresh their presence at the server to keep directory entries from getting stale in the presence of client application crashes. A flow control mechanism from the server is also described that allows a server to inform clients how often they should refresh their presence.
The protocol described in this document is designed to satisfy some of the operational requirements within the Internet X.509 PKI. Specifically, this document addresses requirements to provide access to PKI repositories for the purposes of retrieving PKI information and managing that same information. The mechanism described in this document is based on the LDAPv2, defined in RFC 1777, defining a profile of that protocol for use within the PKIX and updates encodings for certificates and revocation lists from RFC 1778. Additional mechanisms addressing PKIX operational requirements are specified in separate documents.
LDAP uses X.500-compatible distinguished names for providing unique identification of entries. This document defines an algorithm by which a name registered with the Internet Domain Name Service can be represented as an LDAP distinguished name.
This document describes a method for adding authentication support to connection-based protocols. To use this specification, a protocol includes a command for identifying and authenticating a user to a server and for optionally negotiating protection of subsequent protocol interactions. If its use is negotiated, a security layer is inserted between the protocol and the connection. This document describes how a protocol specifies such a command, defines several mechanisms for use by the command, and defines the protocol used for carrying a negotiated security layer over the connection.
This IETF Integrated Directory Services(IDS) Working Group proposes a standard specification for a simple Internet White Pages service by defining a common schema for use by the various White Pages servers. This schema is independent of specific implementations of the White Pages service. This document specifies the minimum set of core attributes of a White Pages entry for an individual and describes how new objects with those attributes can be defined and published. It does not describe how to represent other objects in the White Pages service. Further, it does not address the search sort expectations within a particular service.
MIXER (RFC 2156) defines an algorithm for use of a set of global mapping between X.400 and RFC 822 addresses. This specification defines how to represent and maintain these mappings (MIXER Conformant Global Address Mappings of MCGAMs) in an X.500 or LDAP directory. Mechanisms for representing OR Address and Domain hierarchies within the DIT. These techniques are used to define two independent subtrees in the DIT, which contain the mapping information.
RFC-2079 Definition of an X.500 Attribute Type and an Object Class to Hold Uniform Resource Identifiers
URLs are being widely used to specify the location of Internet resources. There is an urgent need to be able to include URLs in directories that conform to the LDAP and X.500 information models, and a desire to include other types of URIs as they are defined. A number of independent groups are already experimenting with the inclusion of URLs in LDAP and X.500 directories. This document builds on the experimentation to date and defines a new attribute type and an auxiliary object class to allow URIs, including URLs, to be stored in directory entries in a standard way.
The Lightweight Directory Access Protocol (LDAP) is extensible. It provides mechanisms for adding new operations, extending existing operations, and expanding user and system schemas. This document discusses considerations for designers of LDAP extensions.
RFC-4520 Internet Assigned Numbers Authority (IANA) Considerations for the Lightweight Directory Access Protocol (LDAP)
This document provides procedures for registering extensible elements of the Lightweight Directory Access Protocol (LDAP). The document also provides guidelines to the Internet Assigned Numbers Authority (IANA) describing conditions under which new values can be assigned.
The Internet is used for information exchange and communication between its users. It can only be effective as such if users are able to find each other's addresses. Therefore the Internet benefits from an adequate White Pages Service, i.e., a directory service offering (Internet) address information related to people and organizations.
This document describes the way in which the Internet White Pages Service (from now on abbreviated as IWPS) is best exploited using today's experience, today's protocols, today's products and today's procedures.
RFC-5803 Lightweight Directory Access Protocol (LDAP) Schema for Storing Salted Challenge Response Authentication Mechanism (SCRAM) Secrets
This memo describes how the "authPassword" Lightweight Directory Access Protocol (LDAP) attribute can be used for storing secrets used by the Salted Challenge Response Authentication Mechanism (SCRAM) mechanism in the Simple Authentication and Security Layer (SASL) framework.
RFC-4876 A Configuration Profile Schema for Lightweight Directory Access Protocol (LDAP)-Based Agents
This document consists of two primary components, a schema for agents that make use of the Lightweight Directory Access protocol (LDAP) and a proposed use case of that schema, for distributed configuration of similar directory user agents. A set of attribute types and an object class are proposed. In the proposed use case, directory user agents (DUAs) can use this schema to determine directory data location and access parameters for specific services they support. In addition, in the proposed use case, attribute and object class mapping allows DUAs to reconfigure their expected (default) schema to match that of the end user's environment. This document is intended to be a skeleton for future documents that describe configuration of specific DUA services.
The Lightweight Directory Access Protocol (LDAP) search operation provides mechanisms for clients to request all user application attributes, all operational attributes, and/or attributes selected by their description. This document extends LDAP to support a mechanism that LDAP clients may use to request the return of all attributes of an object class.
This document describes an extension to the Lightweight Directory Access Protocol (LDAP) Modify operation to support an increment capability. This extension is useful in provisioning applications, especially when combined with the assertion control and/or the pre- read or post-read control extension.
RFC-4403 Lightweight Directory Access Protocol (LDAP) Schema for Universal Description, Discovery, and Integration version 3 (UDDIv3)
This document defines the Lightweight Directory Access Protocol (LDAPv3) schema for representing Universal Description, Discovery, and Integration (UDDI) data types in an LDAP directory. It defines the LDAP object class and attribute definitions and containment rules to model UDDI entities, defined in the UDDI version 3 information model, in an LDAPv3-compliant directory.
The Lightweight Directory Access Protocol (LDAP) Bulk Update/Replication Protocol (LBURP) allows an LDAP client to perform a bulk update to an LDAP server. The protocol frames a sequenced set of update operations within a pair of LDAP extended operations to notify the server that the update operations in the framed set are related in such a way that the ordering of all operations can be preserved during processing even when they are sent asynchronously by the client. Update operations can be grouped within a single protocol message to maximize the efficiency of client-server communication.
The protocol is suitable for efficiently making a substantial set of updates to the entries in an LDAP server.
The International Telecommunications Union Standardization Sector (ITU-T) has created the H.350 series of Recommendations that specify directory services architectures in support of multimedia conferencing protocols. The goal of the architecture is to 'directory enable' multimedia conferencing so that these services can leverage existing identity management and enterprise directories. A particular goal is to enable an enterprise or service provider to maintain a canonical source of users and their multimedia conferencing systems, so that multiple call servers from multiple vendors, supporting multiple protocols, can all access the same data store.
Because SIP is an IETF standard, the contents of H.350 and H.350.4 are made available via this document to the IETF community. This document contains the entire normative text of ITU-T Recommendations H.350 and H.350.4 in sections 4 and 5, respectively. The remaining sections are included only in this document, not in the ITU-T version.
RFC-3829 Lightweight Directory Access Protocol (LDAP) Authorization Identity Request and Response Controls
This document extends the Lightweight Directory Access Protocol (LDAP) bind operation with a mechanism for requesting and returning the authorization identity it establishes. Specifically, this document defines the Authorization Identity Request and Response controls for use with the Bind operation.
This document defines a schema, object classes and attributes, for printers and printer services, for use with directories that support Lightweight Directory Access Protocol v3 (LDAP-TS). This document is based on the printer attributes listed in Appendix E of Internet Printing Protocol/1.1 (IPP) (RFC 2911). A few additional printer attributes are based on definitions in the Printer MIB (RFC 1759).
This document recommends the retirement of version 2 of the Lightweight Directory Access Protocol (LDAPv2) and other dependent specifications, and discusses the reasons for doing so. This document recommends RFC 1777, 1778, 1779, 1781, and 2559 (as well as documents they superseded) be moved to Historic status.
This document discusses the fundamental requirements for replication of data accessible via the Lightweight Directory Access Protocol (version 3) (LDAPv3). It is intended to be a gathering place for general replication requirements needed to provide interoperability between informational directories.
This document describes schema in support of user/password authentication in a LDAP (Lightweight Directory Access Protocol) directory including the authPassword attribute type. This attribute type holds values derived from the user's password(s) (commonly using cryptographic strength one-way hash). authPassword is intended to used instead of userPassword.
This document specifies two Lightweight Directory Access Protocol (LDAP) attributes, vendorName and vendorVersion that MAY be included in the root DSA-specific Entry (DSE) to advertise vendor-specific information. These two attributes supplement the attributes defined in section 3.4 of RFC 2251.
This memo provides a selection of object classes and attribute types for use in conjunction with public-key cryptography and Lightweight Directory Access Protocol (LDAP) accessible directories. It also includes ASN.1 syntax for all constructs.
The strength of the TISDAG (Technical Infrastructure for Swedish Directory Access Gateways) project's DAG proposal is that it defines the necessary technical infrastructure to provide a single-access- point service for information on Swedish Internet users. The resulting service will provide uniform access for all information -- the same level of access to information (7x24 service), and the same information made available, irrespective of the service provider responsible for maintaining that information, their directory service protocols, or the end-user's client access protocol.
This document defines a multipurpose internet mail extensions (MIME) directory profile for holding a lightweight directory access protocol (LDAP) schema. It is intended for communication with the Internet schema listing service.
This document describes a procedure for mapping between Service Location Protocol (SLP) service advertisements and lightweight directory access protocol (LDAP) descriptions of services. The document covers two aspects of the mapping. One aspect is mapping between SLP service type templates and LDAP directory schema. Because the SLP service type template grammar is relatively simple, mapping from service type templates to LDAP types is straightforward. Mapping in the other direction is straightforward if the attributes are restricted to use just a few of the syntaxes defined in RFC 2252. If arbitrary ASN.1 types occur in the schema, then the mapping is more complex and may even be impossible. The second aspect is representation of service information in an LDAP directory. The recommended representation simplifies interoperability with SLP by allowing SLP directory agents to backend into LDAP directory servers. The resulting system allows service advertisements to propagate easily between SLP and LDAP.
This document describes the fundamental requirements of an access control list (ACL) model for the LDAP directory service. It is intended to be a gathering place for access control requirements needed to provide authorized access to and interoperability between directories.
While the X.500 standards define many useful attribute types [X520] and object classes [X521], they do not define a person object class that meets the requirements found in today's Internet and Intranet directory service deployments. We define a new object class called inetOrgPerson for use in LDAP and X.500 directory services that extends the X.521 standard organizationalPerson class to meet these needs.
CORBA is the Common Object Request Broker Architecture defined by the Object Management Group. This document defines the schema for representing CORBA object references in an LDAP directory.
This document defines the schema for representing Java objects in an LDAP directory. It defines schema elements to represent a Java serialized object, a Java marshalled object, a Java remote object, and a JNDI reference.
This document describes an LDAPv3 control extension for simple paging of search results. This control extension allows a client to control the rate at which an LDAP server returns the results of an LDAP search operation. This control may be useful when the LDAP client has limited resources and may not be able to process the entire result set from a given LDAP query, or when the LDAP client is connected over a low-bandwidth connection. Other operations on the result set are not defined in this extension. This extension is not designed to provide more sophisticated result set management.
This document defines a C language application program interface to LDAP, which is designed to be powerful, yet simple to use. It defines compatible synchronous and asynchronous interfaces to LDAP to suit a wide variety of applications. This document gives a brief overview of the LDAP model, then an overview of how the API is used by an application program to obtain LDAP information. The API calls are described in detail, followed by an appendix that provides some example code demonstrating the use of the API.
Lightweight Directory Access Protocol (LDAP) update operations, such as Add, Delete, and Modify operations, have atomic, consistency, isolation, durability (ACID) properties. Each of these update operations act upon an entry. It is often desirable to update two or more entries in a single unit of interaction, a transaction. Transactions are necessary to support a number of applications including resource provisioning. This document extends LDAP to support transactions.
This specification describes the Lightweight Directory Access Protocol (LDAP) Content Synchronization Operation. The operation allows a client to maintain a copy of a fragment of the Directory Information Tree (DIT). It supports both polling for changes and listening for changes. The operation is defined as an extension of the LDAP Search Operation.
This specification describes a Lightweight Directory Access Protocol (LDAP) extended operation to reverse (or "turn") the roles of client and server for subsequent protocol exchanges in the session, or to enable each peer to act as both client and server with respect to the other.
Domain registration data has typically been exposed to the general public via Nicname/Whois for administrative purposes. This document describes the Referral Lightweight Directory Access Protocol (LDAP) Service, an experimental service using LDAP and well-known LDAP types to make domain administrative data available.
The OpenLDAP Project is operating an experimental LDAP (Lightweight Directory Access Protocol) referral service known as the "OpenLDAP Root Service". The automated system generates referrals based upon service location information published in DNS SRV RRs (Domain Name System location of services resource records). This document describes this service.
LDAPv2 clients as implemented according to RFC 1777 have no notion of referral. The integration between such a client and an Index Mesh, as defined by the Common Indexing Protocol, heavily depends on referrals and therefore needs to be handled in a special way. This document defines one possible way of doing this.
This document defines an LDAPv3 based mechanism for signing directory operations in order to create a secure journal of changes that have been made to each directory entry. Both client and server based signatures are supported. An object class for subsequent retrieval are 'journal entries' is also defined. This document specifies LDAPv3 controls that enable this functionality. It also defines an LDAPv3 schema that allows for subsequent browsing of the journal information.
This document describes an experimental mechanism for mapping entities related to TCP/IP and the UNIX system into X.500 entries so that they may be resolved with the LDAP. A set of attribute types and object classes are proposed, along with specific guidelines for interpreting them. The intention is to assist the deployment of LDAP as an organizational nameservice. No proposed solutions are intended as standards for the Internet. Rather, it is hoped that a general consensus will emerge as to the appropriate solution to such problems, leading eventually to the adoption of standards. The proposed mechanism has already been implemented with some success.
Organizations running multiple directory servers need an ability for administrators to determine who is responsible for a particular server. This is conceptually similar to the 'sysContact' object of SNMP. The administratorsAddress attribute allows a server administrator to provide the contact information of the responsible party for an LDAP server. This can be used by management clients which are, for example, checking the state of a replication or referral topology, to provide a way for the user of the management client to send email to manager of a particular server.
This document defines the Lightweight Directory Access Protocol (LDAP) No-Op control which can be used to disable the normal effect of an operation. The control can be used to discover how a server might react to a particular update request without updating the directory.
Each attribute stored in a Lightweight Directory Access Protocol (LDAP) directory has a defined syntax (i.e., data type). A syntax definition specifies how attribute values conforming to the syntax are normally represented when transferred in LDAP operations. This representation is referred to as the LDAP-specific encoding to distinguish it from other methods of encoding attribute values. This document introduces a new category of attribute options, called transfer encoding options, that can be used to specify that the associated attribute values are encoded according to one of these other methods.
This document defines an 'namedObject' structural object class for the Lightweight Directory Access Protocol (LDAP) and X.500. This is useful for entries with no natural choice of structural object class, e.g. if an entry must exist even though its contents are uninteresting.
As LDAP is used more extensively for managing various kinds of data, one often encounters a need to preserve both the ordering and the content of data, despite the inherently unordered structure of entries and attribute values in the directory. This document describes a scheme to attach ordering information to attributes in a directory so that the ordering may be preserved and propagated to other LDAP applications.
In order to facilitate remote administration and auditing of LDAP server operation, it is desirable to provide the server's operational logs themselves as a searchable LDAP directory. These logs may also be used as a persistent change log to support various replication mechanisms. This document defines a schema that may be used to represent all of the requests that have been processed by an LDAP server. It may be used by various applications for auditing, flight recorder, replication, and other purposes.
This document defines the Lightweight Directory Access Protocol (LDAP) Relax Rules Control which allows a directory user agent (a client) to request the directory service temporarily relax enforcement of various data and service model rules.
This document defines a new DHCP option for delivering configuration information for LDAP services. Through this option, the client receives an LDAP URL  of the closest available LDAP server/replica that can be used to authenticate users or look up any useful data.
This document describes Attribute Types and an Object Class for use in representing XRI (eXtensible Resource Identifier) values in LDAP (Lightweight Directory Access Protocol) and X.500 directory services.
Many network devices, application servers, and middleware components of a enterprise software infrastructure generate some form of session tracking identifiers, which are useful when analyzing activity and accounting logs to group activity relating to a particular session. This document discusses how Lightweight Directory Access Protocol version 3 (LDAP) clients can include session tracking identifiers with their LDAP requests. This information is provided through controls in the requests the clients send to LDAP servers. The LDAP server receiving these controls can include the session tracking identifiers the the log messages it writes, enabling LDAP requests in the LDAP server's logs to be correlated with activity in logs of other components in the infrastructure. The control also enables session tracking information to be generated by LDAP servers and returned to clients and other servers. Three formats of session tracking identifiers are defined in this document.
This document defines an attribute that enables administrative clients using the Lightweight Directory Access Protocol (LDAP) to determine the source of directory entries.
This document defines two controls that extend the LDAPv3 search operation to provide a simple mechanism by which an LDAP client can receive notification of changes that occur in an LDAP server. The mechanism is designed to be very flexible yet easy for clients and servers to implement.
This document describes a Virtual List View control extension for the LDAP Search operation. This control is designed to allow the "virtual list box" feature, common in existing commercial e-mail address book applications, to be supported efficiently by LDAP servers. LDAP servers' inability to support this client feature is a significant impediment to LDAP replacing proprietary protocols in commercial e-mail systems.
The control allows a client to specify that the server return, for a given LDAP search with associated sort keys, a contiguous subset of the search result set. This subset is specified in terms of offsets into the ordered list, or in terms of a greater than or equal comparison value.
Latest information on the RFCs and drafts around LDAP can be found at IETF's datatracker.