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238 lines
12 KiB
Plaintext
238 lines
12 KiB
Plaintext
# $OpenLDAP$
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# Copyright 1999-2000, The OpenLDAP Foundation, All Rights Reserved.
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# COPYING RESTRICTIONS APPLY, see COPYRIGHT.
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H1: Introduction to slapd and slurpd
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This document describes how to build, configure, and run the stand-alone
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LDAP daemon ({{I:slapd}}) and the stand-alone LDAP update replication
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daemon ({{I:slurpd}}). It is intended for newcomers and experienced
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administrators alike. This section provides a basic introduction to directory
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service, and the directory service provided by {{I:slapd}} in particular.
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H2: What is a directory service?
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A directory is like a database, but tends to contain more descriptive,
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attribute-based information. The information in a directory is generally read
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much more often than it is written. As a consequence, directories don't
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usually implement the complicated transaction or roll-back schemes regular
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databases use for doing high-volume complex updates. Directory updates
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are typically simple all-or-nothing changes, if they are allowed at all.
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Directories are tuned to give quick-response to high-volume lookup or
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search operations. They may have the ability to replicate information widely in
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order to increase availability and reliability, while reducing response time.
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When directory information is replicated, temporary inconsistencies between
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the replicas may be OK, as long as they get in sync eventually.
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There are many different ways to provide a directory service. Different
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methods allow different kinds of information to be stored in the directory,
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place different requirements on how that information can be referenced,
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queried and updated, how it is protected from unauthorized access, etc.
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Some directory services are {{I:local}}, providing service to a restricted
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context (e.g., the finger service on a single machine). Other services are
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global, providing service to a much broader context (e.g., the entire Internet).
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Global services are usually {{I:distributed}},
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meaning that the data they contain
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is spread across many machines, all of which cooperate to provide the
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directory service. Typically a global service defines a uniform {{I:namespace}}
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which gives the same view of the data no matter where you are in relation to
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the data itself.
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H2: What is LDAP?
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{{I:Slapd}}'s model for directory service is based on a global directory model
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called LDAP, which stands for the Lightweight Directory Access Protocol.
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LDAP is a directory service protocol that runs over TCP/IP. The nitty-gritty
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details of LDAP are defined in RFC 1777 "The Lightweight Directory Access
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Protocol." This section gives an overview of LDAP from a user's perspective.
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{{I:What kind of information can be stored in the directory?}}
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The LDAP directory
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service model is based on {{I:entries}}. An entry is a collection of
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attributes that has a name, called a {{I:distinguished name}} (DN).
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The DN is used to refer to the entry unambiguously. Each of the
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entry's attributes has a {{I:type}} and one or
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more {{I:values}}.
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The types are typically mnemonic strings, like "{{EX:cn}}" for common
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name, or "{{EX:mail}}" for email address. The values depend on what type of
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attribute it is. For example, a {{EX:mail}} attribute might contain the value
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"{{EX:babs@openldap.org}}". A {{EX:jpegPhoto}} attribute would contain
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a photograph in binary JPEG/JFIF format.
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{{I:How is the information arranged?}}
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In LDAP, directory entries are arranged in
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a hierarchical tree-like structure that reflects political, geographic and/or
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organizational boundaries. Entries representing countries appear at the top
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of the tree. Below them are entries representing states or national
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organizations. Below them might be entries representing people,
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organizational units, printers, documents, or just about anything else you can
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think of. Figure 1 shows an example LDAP directory tree, which should help
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make things clear.
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!import "intro_tree.gif"; align="center"; title="An example LDAP directory tree"
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FT[align="Center"] Figure 1: An example LDAP directory tree.
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In addition, LDAP allows you to control which attributes are required and
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allowed in an entry through the use of a special attribute called
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{{I:objectclass}}.
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The values of the {{I:objectclass}} attribute determine
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the {{I:schema}} rules the entry
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must obey.
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{{I:How is the information referenced?}}
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An entry is referenced by its
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distinguished name, which is constructed by taking the name of the entry
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itself (called the relative distinguished name, or RDN) and concatenating the
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names of its ancestor entries. For example, the entry for Barbara Jensen in
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the example above has an RDN of "{{EX:cn=Barbara J Jensen}}" and a DN of
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"{{EX:cn=Barbara J Jensen, o=OpenLDAP Project, c=US}}". The full DN format is
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described in RFC 1779, "A String Representation of Distinguished Names."
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{{I:How is the information accessed?}}
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LDAP defines operations for interrogating
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and updating the directory. Operations are provided for adding and deleting
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an entry from the directory, changing an existing entry, and changing the
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name of an entry. Most of the time, though, LDAP is used to search for
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information in the directory. The LDAP search operation allows some portion
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of the directory to be searched for entries that match some criteria specified
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by a search filter. Information can be requested from each entry that matches
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the criteria.
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For example, you might want to search the entire directory subtree below the
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OpenLDAP Project for people with the name Barbara Jensen, retrieving
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the email address of each entry found. LDAP lets you do this easily. Or you
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might want to search the entries directly below the c=US entry for
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organizations with the string "Acme" in their name, and that have a fax
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number. LDAP lets you do this too. The next section describes in more detail
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what you can do with LDAP and how it might be useful to you.
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{{I:How is the information protected from unauthorized access?}}
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Some directory
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services provide no protection, allowing anyone to see the information. LDAP
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provides a method for a client to authenticate, or prove its identity to a
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directory server, paving the way for rich access control to protect the
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information the server contains.
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H2: How does LDAP work?
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LDAP directory service is based on a {{I:client-server}} model. One or more
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LDAP servers contain the data making up the LDAP directory tree. An LDAP
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client connects to an LDAP server and asks it a question. The server
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responds with the answer, or with a pointer to where the client can get more
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information (typically, another LDAP server). No matter which LDAP server a
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client connects to, it sees the same view of the directory; a name presented
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to one LDAP server references the same entry it would at another LDAP
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server. This is an important feature of a global directory service, like LDAP.
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H2: What is slapd and what can it do?
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{{I:Slapd}} is an LDAP directory server that runs on many different UNIX
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platforms. You can use it to provide a directory service of your very own.
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Your directory can contain pretty much anything you want to put in it. You
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can connect it to the global LDAP directory service, or run a service all by
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yourself. Some of slapd's more interesting features and capabilities include:
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{{B:Choice of databases}}: {{I:Slapd}} comes with three different backend
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databases you can choose from. They are LDBM, a high-performance disk-based
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database; SHELL, a database interface to arbitrary UNIX commands or shell
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scripts; and PASSWD, a simple password file database.
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{{B:Multiple database instances}}: {{I:Slapd}} can be configured to serve
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multiple databases at the same time. This means that a single {{I:slapd}}
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server can respond to requests for many logically different portions
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of the LDAP tree, using the same or different backend databases.
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{{B:Generic database API}}: If you require even more customization, {{I:slapd}}
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lets you write your own backend database easily. {{I:Slapd}}
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consists of two distinct parts: a front end that handles protocol
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communication with LDAP clients; and a backend that handles database
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operations. Because these two pieces communicate via a well-defined
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C API, you can write your own customized database backend to {{I:slapd}}.
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{{B:Access control}}: {{I:Slapd}} provides a rich and powerful access
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control facility, allowing you to control access to the information
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in your database(s). You can control access to entries based on
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LDAP authentication information, IP address, domain name and other criteria.
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{{B:Threads}}: {{I:Slapd}} is threaded for high performance. A
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single multi-threaded {{I:slapd}} process handles all incoming
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requests, reducing the amount of system overhead required. {{I:Slapd}}
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will automatically select the best thread support for your platform.
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{{B:Replication}}: {{I:Slapd}} can be configured to maintain replica
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copies of its database. This master/slave replication scheme is
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vital in high-volume environments where a single {{I:slapd}} just
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doesn't provide the necessary availability or reliability.
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{{B:Configuration}}: {{I:Slapd}} is highly configurable through a
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single configuration file which allows you to change just about
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everything you'd ever want to change. Configuration options have
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reasonable defaults, making your job much easier.
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{{I:Slapd}} also has its limitations, of course. It does not
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currently handle aliases, which are part of the LDAP model. The
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main LDBM database backend does not handle range queries or negation
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queries very well. These features and more will be coming in a future release.
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H2: What about X.500?
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LDAP was originally developed as a front end to X.500, the OSI directory
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service. X.500 defines the Directory Access Protocol (DAP) for clients to
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use when contacting directory servers. DAP is a heavyweight protocol that
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runs over a full OSI stack and requires a significant amount of computing
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resources to run. LDAP runs directly over TCP and provides most of the
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functionality of DAP at a much lower cost.
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This use of LDAP makes it easy to access the X.500 directory, but still
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requires a full X.500 service to make data available to the many LDAP clients
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being developed. As with full X.500 DAP clients, a full X.500 server is no
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small piece of software to run.
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The stand-alone LDAP daemon, or {{I:slapd}}, is meant to remove much of the
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burden from the server side just as LDAP itself removed much of the burden
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from clients. If you are already running an X.500 service and you want to
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continue to do so, you can probably stop reading this guide, which is all
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about running LDAP via {{I:slapd}}, without running X.500. If you are not
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running X.500,
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want to stop running X.500, or have no immediate plans to run X.500,
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read on.
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It is possible to replicate data from a {{I:slapd}} directory
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server to an X.500 DSA, which allows your organization to make your
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data available as part of the global X.500 directory service on a
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"read-only" basis. This is discussed in section 11.6.
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Another way to make data in a {{I:slapd}} server available to the X.500
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community would be by using a X.500 DAP to LDAP gateway. At this time, no
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such software has been written (to the best of our knowledge), but hopefully
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some group will see fit towrite such a gateway.
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H2: What is slurpd and what can it do?
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{{I:Slurpd}} is a UNIX daemon that helps {{I:slapd}} provide
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replicated service. It is responsible for distributing changes made
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to the master {{I:slapd}} database out to the various {{I:slapd}}
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replicas. It frees {{I:slapd}} from having to worry that some
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replicas might be down or unreachable when a change comes through;
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{{I:slurpd}} handles retrying failed requests automatically.
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{{I:Slapd}} and {{I:slurpd}} communicate through a simple text
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file that is used to log changes.
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PB:
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