mirror of
https://git.openldap.org/openldap/openldap.git
synced 2024-12-27 03:20:22 +08:00
316 lines
15 KiB
Plaintext
316 lines
15 KiB
Plaintext
# $OpenLDAP$
|
|
# Copyright 1999-2003, 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 historic ({{REF:RFC3494}}). As most implementations
|
|
(including {{slapd}}(8)) of LDAPv2 do not conform to the LDAPv2
|
|
technical specification, interoperatibility amongst implementations
|
|
claiming LDAPv2 support will be limited. As LDAPv2 differs
|
|
significantly from LDAPv3, 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 and Unix IPC.
|
|
|
|
{{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}} can be configured to restrict
|
|
access at the socket layer based upon network topology information.
|
|
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. The BDB backend utilizes
|
|
{{ORG:Sleepycat}} {{PRD:Berkeley DB}}. The 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 shadow
|
|
copies of directory information. 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 (for use where strong ACID properties
|
|
are not required). {{slapd}} supports two replication methods:
|
|
{{LDAP Sync}}-based and {{slurpd}}(8)-based replication .
|
|
|
|
{{B:Proxy Cache}}: {{slapd}} can be configured as a caching
|
|
LDAP proxy service.
|
|
|
|
{{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.
|
|
|
|
|
|
H2: What is slurpd and what can it do?
|
|
|
|
{{slurpd}}(8) is a daemon that, with {{slapd}} help, provides
|
|
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).
|
|
|
|
Alternatively, {{LDAP-Sync}}-based replication may be used to provide
|
|
a replicated service. See the {{SECT:LDAP Sync Replication}} chapter
|
|
for details.
|
|
|