# $OpenLDAP$ # Copyright 1999-2002, The OpenLDAP Foundation, All Rights Reserved. # COPYING RESTRICTIONS APPLY, see COPYRIGHT. H1: Introduction to OpenLDAP Directory Services This document describes how to build, configure, and operate OpenLDAP software to provide directory services. This includes details on how to configure and run the stand-alone {{TERM:LDAP}} daemon, {{slapd}}(8) and the stand-alone LDAP update replication daemon, {{slurpd}}(8). It is intended for newcomers and experienced administrators alike. This section provides a basic introduction to directory services and, in particular, the directory services provided by {{slapd}}(8). H2: What is a directory service? A directory is a specialized database optimized for reading, browsing and searching. Directories tend to contain descriptive, attribute-based information and support sophisticated filtering capabilities. Directories generally do not support complicated transaction or roll-back schemes found in database management systems designed for handling high-volume complex updates. Directory updates are typically simple all-or-nothing changes, if they are allowed at all. Directories are tuned to give quick response to high-volume lookup or search operations. They may have the ability to replicate information widely in order to increase availability and reliability, while reducing response time. When directory information is replicated, temporary inconsistencies between the replicas may be okay, as long as they get in sync eventually. There are many different ways to provide a directory service. Different methods allow different kinds of information to be stored in the directory, place different requirements on how that information can be referenced, queried and updated, how it is protected from unauthorized access, etc. Some directory services are {{local}}, providing service to a restricted context (e.g., the finger service on a single machine). Other services are global, providing service to a much broader context (e.g., the entire Internet). Global services are usually {{distributed}}, meaning that the data they contain is spread across many machines, all of which cooperate to provide the directory service. Typically a global service defines a uniform {{namespace}} which gives the same view of the data no matter where you are in relation to the data itself. The Internet {{TERM[expand]DNS}} (DNS) is an example of a globally distributed directory service. H2: What is LDAP? {{TERM:LDAP}} stands for {{TERM[expand]LDAP}}. As the name suggests, it is a lightweight protocol for accessing directory services, specifically {{TERM:X.500}}-based directory services. LDAP runs over {{TERM:TCP}}/{{TERM:IP}} or other connection oriented transfer services. The nitty-gritty details of LDAP are defined in {{REF:RFC2251}} "The Lightweight Directory Access Protocol (v3)" and other documents comprising the technical specification {{REF:RFC3377}}. This section gives an overview of LDAP from a user's perspective. {{What kind of information can be stored in the directory?}} The LDAP information model is based on {{entries}}. An entry is a collection of attributes that has a globally-unique {{TERM[expand]DN}} (DN). The DN is used to refer to the entry unambiguously. Each of the entry's attributes has a {{type}} and one or more {{values}}. The types are typically mnemonic strings, like "{{EX:cn}}" for common name, or "{{EX:mail}}" for email address. The syntax of values depend on the attribute type. For example, a {{EX:cn}} attribute might contain the value {{EX:Babs Jensen}}. A {{EX:mail}} attribute might contain the value "{{EX:babs@example.com}}". A {{EX:jpegPhoto}} attribute would contain a photograph in the JPEG (binary) format. {{How is the information arranged?}} In LDAP, directory entries are arranged in a hierarchical tree-like structure. Traditionally, this structure reflected the geographic and/or organizational boundaries. Entries representing countries appear at the top of the tree. Below them are entries representing states and national organizations. Below them might be entries representing organizational units, people, printers, documents, or just about anything else you can think of. Figure 1.1 shows an example LDAP directory tree using traditional naming. !import "intro_tree.gif"; align="center"; \ title="LDAP directory tree (traditional naming)" FT[align="Center"] Figure 1.1: LDAP directory tree (traditional naming) The tree may also be arranged based upon Internet domain names. This naming approach is becoming increasing popular as it allows for directory services to be located using the {{DNS}}. Figure 1.2 shows an example LDAP directory tree using domain-based naming. !import "intro_dctree.gif"; align="center"; \ title="LDAP directory tree (Internet naming)" FT[align="Center"] Figure 1.2: LDAP directory tree (Internet naming) In addition, LDAP allows you to control which attributes are required and allowed in an entry through the use of a special attribute called {{EX:objectClass}}. The values of the {{EX:objectClass}} attribute determine the {{schema}} rules the entry must obey. {{How is the information referenced?}} An entry is referenced by its distinguished name, which is constructed by taking the name of the entry itself (called the {{TERM[expand]RDN}} or RDN) and concatenating the names of its ancestor entries. For example, the entry for Barbara Jensen in the Internet naming example above has an RDN of {{EX:uid=babs}} and a DN of {{EX:uid=babs,ou=People,dc=example,dc=com}}. The full DN format is described in {{REF:RFC2253}}, "Lightweight Directory Access Protocol (v3): UTF-8 String Representation of Distinguished Names." {{How is the information accessed?}} LDAP defines operations for interrogating and updating the directory. Operations are provided for adding and deleting an entry from the directory, changing an existing entry, and changing the name of an entry. Most of the time, though, LDAP is used to search for information in the directory. The LDAP search operation allows some portion of the directory to be searched for entries that match some criteria specified by a search filter. Information can be requested from each entry that matches the criteria. For example, you might want to search the entire directory subtree at and below {{EX:dc=example,dc=com}} for people with the name {{EX:Barbara Jensen}}, retrieving the email address of each entry found. LDAP lets you do this easily. Or you might want to search the entries directly below the {{EX:st=California,c=US}} entry for organizations with the string {{EX:Acme}} in their name, and that have a fax number. LDAP lets you do this too. The next section describes in more detail what you can do with LDAP and how it might be useful to you. {{How is the information protected from unauthorized access?}} Some directory services provide no protection, allowing anyone to see the information. LDAP provides a mechanism for a client to authenticate, or prove its identity to a directory server, paving the way for rich access control to protect the information the server contains. LDAP also supports privacy and integrity security services. H2: How does LDAP work? LDAP directory service is based on a {{client-server}} model. One or more LDAP servers contain the data making up the directory information tree (DIT). The client connects to servers and asks it a question. The server responds with an answer and/or with a pointer to where the client can get additional information (typically, another LDAP server). No matter which LDAP server a client connects to, it sees the same view of the directory; a name presented to one LDAP server references the same entry it would at another LDAP server. This is an important feature of a global directory service, like LDAP. H2: What about X.500? Technically, {{TERM:LDAP}} is a directory access protocol to an {{TERM:X.500}} directory service, the {{TERM:OSI}} directory service. Initially, LDAP clients accessed gateways to the X.500 directory service. This gateway ran LDAP between the client and gateway and X.500's {{TERM[expand]DAP}} ({{TERM:DAP}}) between the gateway and the X.500 server. DAP is a heavyweight protocol that operates over a full OSI protocol stack and requires a significant amount of computing resources. LDAP is designed to operate over {{TERM:TCP}}/{{TERM:IP}} and provides most of the functionality of DAP at a much lower cost. While LDAP is still used to access X.500 directory service via gateways, LDAP is now more commonly directly implemented in X.500 servers. The stand-alone LDAP daemon, or {{slapd}}(8), can be viewed as a {{lightweight}} X.500 directory server. That is, it does not implement the X.500's DAP. As a {{lightweight directory}} server, {{slapd}}(8) implements only a subset of the X.500 models. If you are already running a X.500 DAP service and you want to continue to do so, you can probably stop reading this guide. This guide is all about running LDAP via {{slapd}}(8), without running X.500 DAP. If you are not running X.500 DAP, want to stop running X.500 DAP, or have no immediate plans to run X.500 DAP, read on. It is possible to replicate data from an LDAP directory server to a X.500 DAP {{TERM:DSA}}. This requires an LDAP/DAP gateway. OpenLDAP does not provide such a gateway, but our replication daemon can be used to replicate to such a gateway. See the {{SECT:Replication with slurpd}} chapter of this document for information regarding replication. H2: What is the difference between LDAPv2 and LDAPv3? LDAPv3 was developed in the late 1990's to replace LDAPv2. LDAPv3 adds the following features to LDAP: - Strong Authentication via {{TERM:SASL}} - Integrity and Confidentiality Protection via {{TERM:TLS}} (SSL) - Internationalization through the use of Unicode - Referrals and Continuations - Schema Discovery - Extensibility (controls, extended operations, and more) LDAPv2 is considered historical. As deploying both LDAPv2 and LDAPv3 simultaneously can be quite problematic, LDAPv2 should be avoided. LDAPv2 is disabled by default. H2: What is slapd and what can it do? {{slapd}}(8) is an LDAP directory server that runs on many different platforms. You can use it to provide a directory service of your very own. Your directory can contain pretty much anything you want to put in it. You can connect it to the global LDAP directory service, or run a service all by yourself. Some of slapd's more interesting features and capabilities include: {{B:LDAPv3}}: {{slapd}} implements version 3 of {{TERM[expand]LDAP}}. {{slapd}} supports LDAP over both IPv4 and IPv6. {{B:{{TERM[expand]SASL}}}}: {{slapd}} supports strong authentication services through the use of SASL. {{slapd}}'s SASL implementation utilizes {{PRD:Cyrus}} {{PRD:SASL}} software which supports a number of mechanisms including DIGEST-MD5, EXTERNAL, and GSSAPI. {{B:{{TERM[expand]TLS}}}}: {{slapd}} provides privacy and integrity protections through the use of TLS (or SSL). {{slapd}}'s TLS implementation utilizes {{PRD:OpenSSL}} software. {{B:Topology control}}: {{slapd}} allows one to restrict access to the server based upon network topology. This feature utilizes {{TCP wrappers}}. {{B:Access control}}: {{slapd}} provides a rich and powerful access control facility, allowing you to control access to the information in your database(s). You can control access to entries based on LDAP authorization information, {{TERM:IP}} address, domain name and other criteria. {{slapd}} supports both {{static}} and {{dynamic}} access control information. {{B:Internationalization}}: {{slapd}} supports Unicode and language tags. {{B:Choice of database backends}}: {{slapd}} comes with a variety of different database backends you can choose from. They include {{TERM:BDB}}, a high-performance transactional database backend; {{TERM:LDBM}}, a lightweight DBM based backend; {{SHELL}}, a backend interface to arbitrary shell scripts; and PASSWD, a simple backend interface to the {{passwd}}(5) file. BDB utilizes {{ORG:Sleepycat}} {{PRD:Berkeley DB}}. LDBM utilizes either {{PRD:Berkeley DB}} or {{PRD:GDBM}}. {{B:Multiple database instances}}: {{slapd}} can be configured to serve multiple databases at the same time. This means that a single {{slapd}} server can respond to requests for many logically different portions of the LDAP tree, using the same or different database backends. {{B:Generic modules API}}: If you require even more customization, {{slapd}} lets you write your own modules easily. {{slapd}} consists of two distinct parts: a front end that handles protocol communication with LDAP clients; and modules which handle specific tasks such as database operations. Because these two pieces communicate via a well-defined {{TERM:C}} {{TERM:API}}, you can write your own customized modules which extend {{slapd}} in numerous ways. Also, a number of {{programmable database}} modules are provided. These allow you to expose external data sources to {{slapd}} using popular programming languages ({{PRD:Perl}}, {{shell}}, {{PRD:SQL}}, and {{PRD:TCL}}). {{B:Threads}}: {{slapd}} is threaded for high performance. A single multi-threaded {{slapd}} process handles all incoming requests using a pool of threads. This reduces the amount of system overhead required while providing high performance. {{B:Replication}}: {{slapd}} can be configured to maintain replica copies of its database. This {{single-master/multiple-slave}} replication scheme is vital in high-volume environments where a single {{slapd}} just doesn't provide the necessary availability or reliability. {{slapd}} also includes experimental support for {{multi-master}} replication. {{B:Configuration}}: {{slapd}} is highly configurable through a single configuration file which allows you to change just about everything you'd ever want to change. Configuration options have reasonable defaults, making your job much easier. {{slapd}} also has its limitations, of course. The main BDB backend does not handle range queries or negation queries very well. H2: What is slurpd and what can it do? {{slurpd}}(8) is a daemon that helps {{slapd}} provide replicated service. It is responsible for distributing changes made to the master {{slapd}} database out to the various {{slapd}} replicas. It frees {{slapd}} from having to worry that some replicas might be down or unreachable when a change comes through; {{slurpd}} handles retrying failed requests automatically. {{slapd}} and {{slurpd}} communicate through a simple text file that is used to log changes. See the {{SECT:Replication with slurpd}} chapter for information about how to configure and run {{slurpd}}(8).