Administration Guide

Red Hat Directory Server 10

Updated for Directory Server 10.3

Marc Muehlfeld

Red Hat Customer Content Services

Petr Bokoč

Red Hat Customer Content Services

Tomáš Čapek

Red Hat Customer Content Services

Petr Kovář

Red Hat Customer Content Services

Ella Deon Ballard

Red Hat Customer Content Services

Abstract

This guide covers both GUI and command-line procedures for managing Directory Server instances and databases.

Chapter 1. Basic Red Hat Directory Server Settings

The Red Hat Directory Server includes a directory service, an administration server to manage multiple server instances, and a Java-based console to manage server instances through a graphical interface. This chapter provides an overview of the basic tasks for administering a directory service.
The Directory Server is a robust, scalable server designed to manage an enterprise-wide directory of users and resources. It is based on an open-systems server protocol called the Lightweight Directory Access Protocol (LDAP). The server manages the directory databases and responds to client requests.
Directory Server is comprised of several components, which work in tandem:
  • The Directory Server is the core LDAP server daemon. It is compliant with LDAP v3 standards. This component includes command-line server management and administration programs and scripts for common operations like export and backing up databases.
  • The Directory Server Console is the user interface that simplifies management of users, groups, and other LDAP data. The Console is used for all aspects of the server management, including backups; security, replication, or databases configuration; server monitoring; and viewing statistics.
  • The Administration Server is the management agent which administers Directory Server instances. It communicates with the Directory Server Console and performs operations on the Directory Server instances. It also provides a simple HTML interface and online help pages.
You can administer Directory Server by using command-line utilities, but it is also possible to use the Directory Server Console.

1.1. System Requirements

See the corresponding section in the Red Hat Directory Server 10 Release Notes.

1.2. File Locations

1.3. Starting the Directory Server Management Console

The Management Console provides a graphical user interface that enables you to perform administrative tasks, such as:
  • Managing Directory Server instances
  • Managing the Administration Server
  • Managing users and groups

Note

The Management Console uses Java. For details about the supported Java runtime environments and versions, see the Red Hat Directory Server Release Notes.
To open the Management Console, enter:
# redhat-idm-console
For supported command-line options, see the corresponding section in the Red Hat Directory Server Configuration, Command, and File Reference.

1.3.1. Opening the Directory Server Console

  1. Start the Directory Server Management Console:
    # redhat-idm-console
  2. Log in as the cn=Directory Manager user:
  3. On the Servers and Applications tab, navigate to administration_domain_namehost_nameServer GroupDirectory Server (instance_name), and click Open.

1.3.2. Opening the Administration Server Console

  1. Start the Directory Server Management Console:
    # redhat-idm-console
  2. Log in as the cn=Directory Manager user:
  3. On the Servers and Applications tab, navigate to administration_domain_namehost_nameServer GroupAdministration Server, and click Open.

1.4. Starting and Stopping a Directory Server Instance

1.4.1. Starting and Stopping a Directory Server Instance Using the Command Line

Use the systemctl utility to start, stop, or restart an instance:
  • To start an instance:
    # systemctl start dirsrv@instance_name
  • To stop an instance:
    # systemctl stop dirsrv@instance_name
  • To restart an instance:
    # systemctl restart dirsrv@instance_name
Optionally, you can enable Directory Server instances to automatically start when the system boots:
  • for a single instance:
    # systemctl enable dirsrv@instance_name
  • for all instances on a server:
    # systemctl enable dirsrv.target
For further details, see the Managing System Services section in the Red Hat System Administrator's Guide.

1.4.2. Starting and Stopping a Directory Server Instance Using the Console

Besides the command line, you can use the Directory Server Console to start, stop, or restart instances.

Important

If you run SELinux in enforcing mode, you cannot use the Console to start or stop an instance. To work around the problem, use the command line to manage the services. See Section 1.4, “Starting and Stopping a Directory Server Instance”.

Important

If you enabled TLS encryption for an instance, Directory Server prompts for the TLS certificate password when the instance starts. The Directory Server Console does not support displaying this password prompt in the GUI. To work around the problem:
To start, stop, or restart a Directory Server instance:
  1. Start the Directory Server Console and log in using the cn=Directory Manager user name.
  2. On the Servers and Applications tab, navigate to administration_domain_namehost_nameServer GroupDirectory Server (instance_name), and click Open.
  3. On the Tasks tab, click the task you want to execute:
  4. Click Yes to confirm.
After the task finished, the console displays a message if the operation was successful or failed.

1.5. Starting and Stopping the Directory Server Administration Server Service

The Administration Server provides the Directory Server Console — a GUI to manage Directory Server.

1.5.1. Starting and Stopping the Administration Server Service Using the Command Line

Use the systemctl utility to start, stop, or restart the Administration Server service:
  • To start the service:
    # systemctl start dirsrv-admin
  • To stop the service:
    # systemctl stop dirsrv-admin
  • To restart the service:
    # systemctl restart dirsrv-admin
Optionally, enable the Administration Server to automatically start when the system boots:
# systemctl enable dirsrv-admin
For further details, see the Managing System Services section in the Red Hat System Administrator's Guide.

1.5.2. Restarting and Stopping the Administration Server Service Using the Console

To restart or stop the Administration Server service:
  1. Start the Directory Server Console and log in using the cn=Directory Manager user name.
  2. On the Servers and Applications tab, navigate to administration_domain_namehost_nameServer GroupAdministration Server, and click Open.
  3. On the Tasks tab, click the task you want to execute:
  4. Click Yes to confirm.
After the task finished, the console displays a message if the operation was successful or failed.

1.6. Enabling LDAPI

Inter-process communication (IPC) is a way for separate processes on a Unix machine or a network to communicate directly with each other. LDAPI allows LDAP connections to run over IPC connections, meaning that LDAP operations can run over Unix sockets. These connections are much faster and more secure than regular LDAP connections.
LDAPI is enabled through two configuration attributes:
  • nsslapd-ldapilisten to enable LDAPI for Directory Server
  • nsslapd-ldapifilepath to point to the Unix socket file
To enable LDAPI:
  1. Modify the nsslapd-ldapilisten to turn LDAPI on and add the socket file attribute.
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn: cn=config
    changetype: modify
    replace: nsslapd-ldapilisten
    nsslapd-ldapilisten: on
    -
    add: nsslapd-ldapifilepath
    nsslapd-ldapifilepath: /var/run/slapd-example.socket
  2. Restart the server to apply the new configuration.
    # systemctl restart dirsrv@instance

1.7. Changing Directory Server Port Numbers

The standard and secure LDAP port numbers used by Directory Server can be changed through the Directory Server Console or by changing the value of the nsslapd-port or nsslapd-secureport attribute under the cn=config entry in the dse.ldif.

Note

Modifying the standard or secure port numbers for a Configuration Directory Server, which maintains the o=NetscapeRoot subtree, should be done through the Directory Server Console.

1.7.1. Changing Standard Port Numbers

  1. In the Directory Server Console, select the Configuration tab, and then select the top entry in the navigation tree in the left pane.
  2. Select the Settings tab in the right pane.
  3. Change the port numbers. The port number for the server to use for non-TLS communications in the Port field, with a default value of 389.
  4. Click Save.
  5. The Console returns a warning, You are about to change the port number for the Configuration Directory. This will affect all Administration Servers that use this directory and you'll need to update them with the new port number. Are you sure you want to change the port number? Click Yes.
  6. Then a dialog appears, reading that the changes will not take effect until the server is restarted. Click OK.

    Note

    Do not restart the Directory Server at this point. If you do, you will not be able to make the necessary changes to the Administration Server through the Console.
  7. Open the Administration Server Console.
  8. In the Configuration tab, select the Configuration DS tab.
  9. In the LDAP Port field, type in the new LDAP port number for your Directory Server instance.
  10. Change the SELinux labels for the Directory Server ports so that the new port number is used in the Directory Server policies. For example:
    # semanage port -a -t ldap_port_t -p tcp 1389

    Warning

    If the SELinux label is not reset, then the Directory Server will not be able to be restarted.
  11. In the Tasks tab of the Directory Server Console, click Restart Directory Server. A dialog to confirm that you want to restart the server. Click Yes.
  12. Open the Configuration DS tab of the Administration Server Console and select Save.
    A dialog will appear, reading The Directory Server setting has been modified. You must shutdown and restart your Administration Server and all the servers in the Server Group for the changes to take effect. Click OK.
  13. In the Tasks tab of the Administration Server Console, click Restart Admin Server. A dialog opens reading that the Administration Server has been successfully restarted. Click Close.

    Note

    You must close and reopen the Console before you can do anything else in the Console. Refresh may not update the Console, and, if you try to do anything, you will get a warning that reads Unable to contact LDAP server.

1.7.2. Changing the LDAPS Port Numbers

Changing the configuration directory or user directory port or secure port numbers has the following repercussions:
  • The Directory Server port number must also be updated in the Administration Server configuration.
  • If there are other Directory Server instances that point to the configuration or user directory, update those servers to point to the new port number.
To modify the LDAPS port:
  1. Make sure that the CA certificate used to issue the Directory Server instance's certificate is in the Administration Server certificate database. Importing CA certificates for the Administration Server is the same as the Directory Server process described in Section 9.3.3, “Installing a CA Certificate”.
  2. The secure port can be configured using the Directory Server Console, much like the process in Section 1.7.1, “Changing Standard Port Numbers” (only setting the value in the Encrypted Port field). However, in some circumstances, such as if there are multiple Directory Server instances on the same machine, where changing port numbers may not be possible through the Directory Server Console. It may be be better to use ldapmodify to change the port number.
    For example:
    # ldapmodify -x -h server.example.com -p 1389 -D "cn=Directory Manager" -W
    dn: cn=config
    replace: nsslapd-securePort
    nsslapd-securePort: 1636
  3. Edit the corresponding port configuration for the Directory Server instance in th Administration Server configuration (o=netscaperoot).
    First, search for the current configuration:
    # ldapsearch -x -h config-ds.example.com -p 389 -D "cn=Directory Manager" -W -b "cn=slapd-ID,cn=389 Directory Server,cn=Server Group,cn=server.example.com,ou=example.com,o=NetscapeRoot" -s base "(objectclass=*)"
    nsSecureServerPort
    
    dn: cn=slapd-ID,cn=389 Directory Server,cn=Server Group,cn=server.example.com,ou=example.com,o=NetscapeRoot
    nsSecureServerPort: 636
    Then, edit the configuration:
    # ldapmodify -x -h config-ds.example.com -p 389 -D "cn=Directory Manager" -W
    
    dn: cn=slapd-ID,cn=389 Directory Server,cn=Server Group,cn=server.example.com,ou=example.com,o=NetscapeRoot
    replace: nsSecureServerPort
    nsSecureServerPort: 1636
  4. Start the Directory Server Console for the instance and confirm that the new LDAPS port number is listed in the Configuration tab.
  5. Optionally, select the Use SSL in Console check box.
  6. Change the SELinux labels for the Directory Server ports so that the new port number is used in the Directory Server policies. For example:
    # semanage port -a -t ldap_port_t -p tcp 1636

    Warning

    If the SELinux label is not reset, then the Directory Server will not be able to be restarted.
  7. Restart the Directory Server instance.

1.8. Managing Directory Server Instances

1.8.1. Creating a New Directory Server Instance

For details, see the corresponding sections in the Red Hat Directory Server Installation Guide:

1.8.2. Removing a Directory Server Instance

1.8.2.1. Removing a Directory Server Instance Using the Command Line

It is possible to remove a single instance of Directory Server without uninstalling all other instances, removing an Administration Server instance, or removing the packages.
# remove-ds.pl -i slapd-instance_name -a
The remove-ds.pl script removes any related files and directories if the -a (all) option is specified. But the Directory Server instance is not unregistered from the Configuration Directory Server.
By default, the key and cert files are left in the instance configuration directory, and the configuration directory is renamed slapd-instance-name.removed. Using the -a option (as shown) removes the security databases, as well.

Note

If there is a problem with the Directory Server, like the installation failed or the server cannot be restarted, then running remove-ds.pl script fails. In this case, try the -f option to force the removal process.
1.8.2.1.1. Removing a Directory Server Instance and Administration Server
It is possible to remove both the Directory Server and the Administration Server (if configured on the same system).
The -y option is required for the script to perform the removal operation. Otherwise, the remove-ds-admin.pl script performs a dry-run but does not remove any servers.
The -a option is not required, but it is recommended if a Directory Server or Administration Server instance may be re-configured on the system later. By default, all of the security databases are preserved by the removal script. The -a option removes the security databases, as well.

Note

The Directory Server instance must be running for the script to bind to the server.

Note

If there is a problem with the Directory Server, like the installation failed or the server cannot be restarted, then running remove-ds-admin.pl script fails. In this case, try the -f option to force the removal process.

1.8.3. Removing a Directory Server Instance Using the Console

  1. Open the Directory Server Console. For details, see Section 1.3.1, “Opening the Directory Server Console”.
  2. Right-click the server instance, and select Remove Server.
  3. Click Yes to confirm.

1.9. Using Directory Server Plug-ins

Directory Server has a number of default plug-ins which configure core Directory Server functions, such as replication, classes of service, and even attribute syntaxes. Core plug-ins are enabled and completely configured by default.
Other default plug-ins extend the functionality of the Directory Server by providing consistent, but user-defined, behaviors, as with DNA, attribute uniqueness, and attribute linking. These plug-ins are available, but not all are enabled or configured by default.
Using plug-ins also allows the Directory Server to be easily extended, so customers can write and deploy their own server plug-ins to perform whatever directory operations they need for their specific deployment.
For further details, see:

1.9.1. Enabling Plug-ins Dynamically

Directory Server supports dynamic plug-ins that can be enabled without restarting the Directory Server. Allowing for dynamically enabled plug-ins makes server administration significantly easier. By using dynamic plug-ins, you can avoid restarting the server multiple times to install and configure the plug-ins. This makes deploying software applications for the Directory Server much faster.
Each plug-in can be enabled or disabled by switching the value of the nsslapd-pluginEnabled attribute. For example:
# ldapmodify -x -D 'cn=Directory Manager' -W
dn: cn=Plug-in_name,cn=plugins,cn=config
changetype: modify
replace: nsslapd-pluginEnabled
nsslapd-pluginEnabled: on
Restarting the Directory Server when plug-ins are reconfigured is not required if you specify the nsslapd-dynamic-plugins switch under the cn=config entry. To enable the dynamic plug-in feature, set the nsslapd-dynamic-plugins attribute to on:
dn: cn=config
nsslapd-dynamic-plugins: on
To disable the dynamic plug-in feature, set the nsslapd-dynamic-plugins attribute to off:
dn: cn=config
nsslapd-dynamic-plugins: off
By default, nsslapd-dynamic-plugins is set to off.

1.9.2. Enabling Plug-ins

1.9.2.1. Enabling Plug-ins in the Command Line

To disable or enable a plug-in through the command line, use the ldapmodify utility to edit the value of the nsslapd-pluginEnabled attribute. For example:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: cn=ACL Plugin,cn=plugins,cn=config
changetype: modify
replace: nsslapd-pluginEnabled
nsslapd-pluginEnabled: on

1.9.2.2. Enabling Plug-ins in the Directory Server Console

To enable and disable plug-ins using the Directory Server Console:
  1. In the Directory Server Console, select the Configuration tab.
  2. Double-click the Plugins folder in the navigation tree.
  3. Select the plug-in from the Plugins list.
  4. To disable the plug-in, clear the Enabled check box. To enable the plug-in, check this check box.
  5. Click Save.
  6. Restart the Directory Server.
    # systemctl restart dirsrv@instance

Note

When a plug-in is disabled, all of the details about the plug-in — such as its version and its vendor — are not displayed in the Directory Server Console; all details fields show NONE.
Once a plug-in is enabled, those details will not be displayed in the Console until the Directory Server is restarted (loading the new plug-in configuration) and the Directory Server Console is refreshed.

1.9.3. Configuring Plug-ins

In Directory Server 9 and earlier, you configured plug-ins using the nsslapd-pluginarg* attributes. Directory Server 10 added support for specific configuration attributes for certain plug-ins.

Important

If both the plug-in-specific configuration attributes and the deprecated nsslapd-pluginarg* attributes are set in a plug-in's configuration, Directory Server only uses settings in plug-in-specific attributes.
The following two examples use the same settings for the Referential Integrity plug-in but using the different configuration options:

Example 1.1. Plug-in Configuration using Configuration Attributes

referint-update-delay: 0
referint-logfile: /var/log/dirsrv/slapd-localhost/referint
referint-logchanges: 0
referint-membership-attr: member
referint-membership-attr: uniquemember
referint-membership-attr: owner
referint-membership-attr: seeAlso

Note

Red Hat recommends using only the configuration plug-in-specific attributes. For plug-in-specific attributes, see the corresponding section in the Red Hat Directory Server Configuration, Command, and File Reference.

Example 1.2. Plug-in Configuration using Plug-in Argument Attributes (Deprecated)

nsslapd-pluginarg0: 0
nsslapd-pluginarg1: /var/log/dirsrv/slapd-localhost/referint
nsslapd-pluginarg2: 0
nsslapd-pluginarg3: member
nsslapd-pluginarg4: uniquemember
nsslapd-pluginarg5: owner
nsslapd-pluginarg6: seeAlso

1.9.3.1. Configuring Plug-ins using the Command Line

To use the ldapmodify utility to configure settings of a plug-in:
  1. Identify the distinguished name (DN) of the plug-in's configuration. For details, see the corresponding section in the Red Hat Directory Server Configuration, Command, and File Reference.
  2. Set the new value. For example, to set the update delay of the Referential Integrity plug-in to 0:
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn: cn=referential integrity postoperation,cn=plugins,cn=config
    changetype: modify
    replace: referint-update-delay
    referint-update-delay: 0
  3. Restart the Directory Server instance:
    # systemctl restart dirsrv@instance_name

1.9.3.2. Configuring Plug-ins using the Console

To use the Directory Server Console to configure settings of a plug-in:
  1. Start the Directory Server Console and log in using the cn=Directory Manager user name.
  2. On the Servers and Applications tab, navigate to administration_domain_namehost_nameServer GroupDirectory Server (instance_name), and click Open.
  3. Navigate to Plug-ins and select the plug-in to configure.
  4. Click the Advanced button in the right panel.

    Note

    Red Hat recommends to configure the plug-in using the Property Editor, which uses the plug-in-specific attributes.
  5. Set the plug-in-specific attributes.
  6. Click OK to close the Property Editor.

1.9.4. Setting the Plug-in Precedence

The plug-in precedence is the priority it has in the execution order of plug-ins. For pre- and post-operation plug-ins, this allows one plug-in to be executed and complete before the next plug-in is initiated, which lets the second plug-in take advantage of the first plug-in's results.
Plug-in precedence is configured in the nsslapd-pluginPrecedence attribute on the plug-in's configuration entry. This attribute has a value of 1 (highest priority) to 99 (lowest priority). If the attribute is not set, it has a default value of 50.

Important

Do not set the plug-in precedence for the default Directory Server plug-ins unless told to do so by Red Hat support. The plug-in precedence attribute is primarily to govern the behavior of custom plug-ins, not to change the behavior of the core Directory Server plug-ins.
The nsslapd-pluginPrecedence attribute is set using the ldapmodify command. For example:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: cn=My Example Plugin,cn=plugins,cn=config
changetype: modify
replace: nsslapd-pluginPrecedence
nsslapd-pluginPrecedence: 1

1.10. Server Configuration Attributes

Directory Server stores the configuration maintained in the cn=config entry in the /etc/dirsrv/slapd-instance_name/dse.ldif file. If you set up a new instance, Directory Server only stores configuration attributes that have been modified in this file. Attributes that are not listed, use their default value.
This enables you to:
  • Identify all configuration parameters set in this instance by displaying the /etc/dirsrv/slapd-instance_name/dse.ldif file.
  • Restore a default value by deleting the parameter.
    If you delete a configuration parameter, the parameter is no longer listed in the /etc/dirsrv/slapd-instance_name/dse.ldif file. However, the parameter and its default value is displayed when you search the parameter in the cn=config entry using the LDAP protocol.
    Note that you cannot delete the parameters listed in Table 1.1, “Configuration Attributes That Cannot Be Deleted” to reset them to their default. If you try to delete them, the server will reject the request with a Server is unwilling to perform (53) error.
  • Use the latest default values provided by a new Directory Server version.
    New versions often provide optimized settings and increased security. For example, if you do not set the passwordStorageScheme attribute, Directory Server automatically uses the strongest supported password storage scheme available. If a future update changes the default value to increase security, passwords will be automatically encrypted using the new storage scheme when a user set a passwords.

    Note

    If you manually set a parameter to the same value as its default, the value is not updated. This happens, when a newer version uses a different default value.

Table 1.1. Configuration Attributes That Cannot Be Deleted

nsslapd-accesslog nsslapd-auditlog nsslapd-bakdir
nsslapd-certdir nsslapd-certmap-basedn nsslapd-conntablesize
nsslapd-errorlog nsslapd-instancedir nsslapd-ldifdir
nsslapd-localhost nsslapd-localuser nsslapd-lockdir
nsslapd-rootpw nsslapd-referral nsslapd-referralmode
nsslapd-rundir nsslapd-saslpath nsslapd-schemadir
nsslapd-tmpdir nsslapd-workingdir

Chapter 2. Configuring Directory Databases

The directory is made up of databases, and the directory tree is distributed across the databases. This chapter describes how to create suffixes, the branch points for the directory tree, and how to create the databases associated with each suffix. This chapter also describes how to create database links to reference databases on remote servers and how to use referrals to point clients to external sources of directory data.

2.1. Creating and Maintaining Suffixes

Different pieces of the directory tree can be stored in different databases, and then these databases can be distributed across multiple servers. The directory tree contains branch points called nodes. These nodes may be associated with databases. A suffix is a node of the directory tree associated with a particular database. For example, a simple directory tree might appear as illustrated in Figure 2.1, “A Directory Tree with One Root Suffix”.
A Directory Tree with One Root Suffix

Figure 2.1. A Directory Tree with One Root Suffix

The ou=people suffix and all the entries and nodes below it might be stored in one database, the ou=groups suffix in another database, and the ou=contractors suffix in yet another database.

2.1.1. Creating Suffixes

A root suffix is the parent of a sub suffix. It can be part of a larger tree designed for the Directory Server. A sub suffix is a branch underneath a root suffix. Both root and sub suffixes are used to organize the contents of the directory tree. The data for root and sub suffixes are contained in databases.
A directory might contain more than one root suffix. For example, an ISP might host several websites, one for example.com and one for redhat.com. Here, two root suffixes are required, one corresponding to the dc=example,dc=com naming context and one corresponding to the dc=redhat,dc=com naming context, as shown in Figure 2.2, “A Directory Tree with Two Root Suffixes”.
A Directory Tree with Two Root Suffixes

Figure 2.2. A Directory Tree with Two Root Suffixes

It is also possible to create root suffixes to exclude portions of the directory tree from search operations. For example, Example Corporation wants to exclude their European office from a search on the general Example Corporation directory. To do this, they create two root suffixes. One root suffix corresponds to the general Example Corporation directory tree, dc=example,dc=com, and one root suffix corresponds to the European branch of their directory tree, l=europe,dc=example,dc=com. From a client application's perspective, the directory tree looks as illustrated in Figure 2.3, “A Directory Tree with a Root Suffix Off Limits to Search Operations”.
A Directory Tree with a Root Suffix Off Limits to Search Operations

Figure 2.3. A Directory Tree with a Root Suffix Off Limits to Search Operations

Searches performed by client applications on the dc=example,dc=com branch of the directory will not return entries from the l=europe,dc=example,dc=com branch of the directory, as it is a separate root suffix.
If you wanted to include entries in the European branch of the directory tree in general searches, you could make the European branch a sub suffix of the general branch. To do this, create a root suffix for Example Corporation, dc=example,dc=com, and then create a sub suffix beneath it for the European directory entries, l=europe,dc=example,dc=com. From a client application's perspective, the directory tree would appear as illustrated in Figure 2.4, “A Directory Tree with a Sub Suffix”.
A Directory Tree with a Sub Suffix

Figure 2.4. A Directory Tree with a Sub Suffix

This section describes creating root and sub suffixes for the directory using either the Directory Server Console or the command line.

2.1.1.1. Creating a New Root Suffix Using the Console

  1. In the Directory Server Console, select the Configuration tab.
  2. Right-click Data in the left navigation pane, and select New Root Suffix from the pop-up menu.
  3. Enter a unique suffix in the New suffix field.
    The suffix must be named in line with dc naming conventions, such as dc=example,dc=com.
  4. Select the Create associated database automatically to create a database at the same time as the new root suffix, and enter a unique name for the new database in the Database name field, such as example2. The name can be a combination of alphanumeric characters, dashes (-), and underscores (_). No other characters are allowed.
    Deselect the check box to create a database for the new root suffix later. This option specifies a directory where the database will be created. The new root suffix will be disabled until a database is created.
The new root suffix is listed under the Data folder.

2.1.1.2. Creating a New Sub Suffix Using the Console

  1. In the Directory Server Console, select the Configuration tab.
  2. Under the Data in the left navigation pane, select the suffix under which to add a new sub suffix. Right-click the suffix, and select New Sub Suffix from the pop-up menu.
    The Create new sub suffix dialog box is displayed.
  3. Enter a unique suffix name in the New suffix field. The suffix must be named in line with dc naming conventions, for example ou=groups.
    The root suffix is automatically added to the name. For example, if the sub suffix ou=groups is created under the dc=example,dc=com suffix, the Console automatically names it ou=groups,dc=example,dc=com.
  4. Select the Create associated database automatically check box to create a database at the same time as the new sub suffix, and enter a unique name for the new database in the Database name field, such as example2. The name can be a combination of alphanumeric characters, dashes (-), and underscores (_). No other characters are allowed.
    If the check box is not selected, than the database for the new sub suffix must be created later. The new sub suffix is disabled until a database is created.
The suffix appears automatically under its root suffix in the Data tree in the left navigation pane.

2.1.1.3. Creating Root and Sub Suffixes using the Command Line

The suffix configuration information is stored in the cn=mapping tree,cn=config entry. Use the ldapmodify utility to add new suffixes to the directory.
For a list of all parameters you can set when creating a suffix, see the corresponding section in the Red Hat Directory Server Configuration, Command, and File Reference.

Creating a Root Suffix

For example, to add the dc=example,dc=com root suffix:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: cn="dc=example,dc=com",cn=mapping tree,cn=config
changetype: add
cn: dc=example,dc=com
objectclass: top
objectclass: extensibleObject
objectclass: nsMappingTree
nsslapd-state: backend
nsslapd-backend: UserData

Creating a Sub Suffix

Creating a sub suffix is similar to creating a root suffix. The difference is that you additionally set the parent suffix in the nsslapd-parent-suffix.
For example, to create the ou=groups sub suffix under the dc=example,dc=com root suffix:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: cn="ou=groups,dc=example,dc=com",cn=mapping tree,cn=config
changetype: add
cn: ou=groups,dc=example,dc=com
objectclass: top
objectclass: extensibleObject
objectclass: nsMappingTree
nsslapd-state: backend
nsslapd-backend: GroupData
nsslapd-parent-suffix: dc=example,dc=com

2.1.2. Maintaining Suffixes

2.1.2.1. Viewing the Default Naming Context

A naming context is analogous to the suffix; it is the root structure for naming directory entries. There can be multiple naming contexts, depending on the directory and data structure. For example, a standard Directory Server configuration has a user suffix such as dc=example,dc=com, a configuration suffix in cn=config, and an administrative configuration suffix in o=netscaperoot.
Many directory trees have multiple naming contexts to be used with different types of entries or with logical data divisions. Clients which access the Directory Server may not know what naming context they need to use. The Directory Server has a server configuration attribute which signals to clients what the default naming context is, if they have no other naming context configuration known to them.
The default naming context is set in the nsslapd-defaultnamingcontext attribute in cn=config. This value is propagated over to the root DSE (Directory Server Agent Service Entry) and can be queried by clients anonymously by checking the defaultnamingcontext attribute in the root DSE:
# ldapsearch -p 389 -h server.example.com -x -b "" -s base | egrep namingcontext
namingContexts: dc=example,dc=com
namingContexts: dc=example,dc=net
namingContexts: dc=redhat,dc=com
defaultnamingcontext: dc=example,dc=com

Important

To maintain configuration consistency, do not remove the nsslapd-defaultnamingcontext attribute from the nsslapd-allowed-to-delete-attrs list.
By default, the nsslapd-defaultnamingcontext attribute is included in the list of attributes which can be deleted, in the nsslapd-allowed-to-delete-attrs attribute. This allows the current default suffix to be deleted and then update the server configuration accordingly.
If for some reason the nsslapd-defaultnamingcontext attribute is removed from the list of configuration attributes which can be deleted, then no changes to that attribute are preserved. If the default suffix is deleted, that change cannot be propagated to the server configuration. This means that the nsslapd-defaultnamingcontext attribute retains the old information instead of being blank (removed), which is the correct and current configuration.

2.1.2.2. Disabling a Suffix

In certain situations, a suffix in the directory needs to be disabled. If a suffix is disabled, the content of the database related to the suffix are no longer accessible by clients.
2.1.2.2.1. Disabling a Suffix Using the Command Line
To disable a suffix using the command line, set the nsslapd-state attribute of the corresponding suffix entry to disabled:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
dn: cn=suffix_DN,cn=mapping tree,cn=config
changetype: modify
replace: nsslapd-state
nsslapd-state: disabled
2.1.2.2.2. Disabling a Suffix Using the Console
To disable a suffix using the Console:
  1. In the Directory Server Console, select the Configuration tab.
  2. Under Data in the left navigation pane, click the suffix to disable.
  3. Click the Suffix Setting tab, and deselect the Enable this suffix check box.

2.1.2.3. Deleting a Suffix

If a suffix is no longer required, delete it from the database.

Warning

Deleting a suffix also deletes all database entries and replication information associated with that suffix.
2.1.2.3.1. Deleting a Suffix Using the Command Line
To delete a suffix using the command line:
  1. Delete the suffix from the mapping tree:
    # ldapdelete -D "cn=Directory Manager" -W -p 389 -h server.example.com -x "cn="suffix_DN",cn=mapping tree,cn=config"
  2. If the suffix uses a separate database, delete the database:
    # ldapdelete -D "cn=Directory Manager" -W -p 389 -h server.example.com -x "cn=database_name,cn=ldbm database,cn=plugins,cn=config"
2.1.2.3.2. Deleting a Suffix Using the Console
To delete a suffix using the Console:
  1. In the Directory Server Console, select the Configuration tab.
  2. Under Data in the left navigation pane, select the suffix to delete.
  3. Right-click the suffix, and select Delete from the menu.
  4. Select either Delete this suffix and all of its sub suffixes or Delete this suffix only.

2.2. Creating and Maintaining Databases

After creating suffixes to organizing the directory data, create databases to contain data of that directory.

2.2.1. Creating Databases

The directory tree can be distributed over multiple Directory Server databases. There are two ways to distribute data across multiple databases:
One database per suffix. The data for each suffix is contained in a separate database.
Three databases are added to store the data contained in separate suffixes:
This division of the tree units corresponds to three databases, for example:
In this example, DB1 contains the data for ou=people and the data for dc=example,dc=com, so that clients can conduct searches based at dc=example,dc=com. However, DB2 only contains the data for ou=groups, and DB3 only contains the data for ou=contractors:
Multiple databases for one suffix.
Suppose the number of entries in the ou=people branch of the directory tree is so large that two databases are needed to store them. In this case, the data contained by ou=people could be distributed across two databases:
DB1 contains people with names from A-K, and DB2 contains people with names from L-Z. DB3 contains the ou=groups data, and DB4 contains the ou=contractors data.
A custom plug-in distributes data from a single suffix across multiple databases. Contact Red Hat Consulting for information on how to create distribution logic for Directory Server.

2.2.1.1. Creating a New Database for an Existing Suffix Using the Console

  1. In the Directory Server Console, select the Configuration tab.
  2. In the left pane, expand Data, then click the suffix to which to add the new database.
  3. Right-click the suffix, and select New Database from the pop-up menu.
  4. Enter a unique name for the database, such as example2. The database name can be a combination of alphanumeric characters, dashes (-), and underscores (_).
    The Create database in field is automatically filled with the default database directory (/var/lib/dirsrv/slapd-instance/db) and the name of the new database. It is also possible to enter or browse for a different directory location.

2.2.1.2. Creating a New Database for a Single Suffix from the Command Line

Use the ldapmodify command-line utility to add a new database to the directory configuration file. The database configuration information is stored in the cn=ldbm database,cn=plugins,cn=config entry. For example, add a new database to the server example1:
  1. Run ldapmodify and create the entry for the new database.
    # ldapmodify -a -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn: cn=UserData,cn=ldbm database,cn=plugins,cn=config
    changetype: add
    objectclass: extensibleObject
    objectclass: nsBackendInstance
    nsslapd-suffix: ou=people,dc=example,dc=com
    The added entry corresponds to a database named UserData that contains the data for the root or sub suffix ou=people,dc=example,dc=com.
  2. Create a root or a sub-suffix, as described in Section 2.1.1.3, “Creating Root and Sub Suffixes using the Command Line”. The database name, given in the DN attribute, must correspond with the value in the nsslapd-backend attribute of the suffix entry.

2.2.1.3. Adding Multiple Databases for a Single Suffix

A single suffix can be distributed across multiple databases. However, to distribute the suffix, a custom distribution function has to be created to extend the directory. For more information on creating a custom distribution function, contact Red Hat Consulting.

Note

Once entries have been distributed, they cannot be redistributed. The following restrictions apply:
  • The distribution function cannot be changed once entry distribution has been deployed.
  • The LDAP modrdn operation cannot be used to rename entries if that would cause them to be distributed into a different database.
  • Distributed local databases cannot be replicated.
  • The ldapmodify operation cannot be used to change entries if that would cause them to be distributed into a different database.
Violating these restrictions prevents Directory Server from correctly locating and returning entries.
After creating a custom distribution logic plug-in, add it to the directory.
The distribution logic is a function declared in a suffix. This function is called for every operation reaching this suffix, including subtree search operations that start above the suffix. A distribution function can be inserted into a suffix using both the Console and the command line interface.
2.2.1.3.1. Adding the Custom Distribution Function to a Suffix Using the Directory Server Console
  1. In the Directory Server Console, select the Configuration tab.
  2. Expand Data in the left navigation pane. Select the suffix to which to apply the distribution function.
  3. Select the Databases tab in the right window.
  4. The databases associated with the suffix are already listed in the Databases tab. Click Add to associate additional databases with the suffix.
  5. Enter the path to the distribution library.
  6. Enter the name of the distribution function in the Function name field.
2.2.1.3.2. Adding the Custom Distribution Function to a Suffix Using the Command Line
  1. Run ldapmodify.
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
  2. Add the following attributes to the suffix entry itself, supplying the information about the custom distribution logic:
    dn: suffix
    changetype: modify
    add: nsslapd-backend
    nsslapd-backend: Database1
    -
    add: nsslapd-backend
    nsslapd-backend: Database2
    -
    add: nsslapd-backend
    nsslapd-backend: Database3
    -
    add: nsslapd-distribution-plugin
    nsslapd-distribution-plugin: /full/name/of/a/shared/library
    -
    add: nsslapd-distribution-funct
    nsslapd-distribution-funct: distribution-function-name
    The nsslapd-backend attribute specifies all databases associated with this suffix. The nsslapd-distribution-plugin attribute specifies the name of the library that the plug-in uses. The nsslapd-distribution-funct attribute provides the name of the distribution function itself.
For more information about using the ldapmodify command-line utility, see Section 3.1, “Managing Entries Using the Command Line”.

2.2.2. Maintaining Directory Databases

2.2.2.1. Placing a Database in Read-Only Mode

When a database is in read-only mode, you cannot create, modify, or delete any entries. One of the situations when read-only mode is useful is for manually initializing a consumer or before backing up or exporting data from the Directory Server. Read-only mode ensures a faithful image of the state of these databases at a given time.
The Directory Server Console and the command-line utilities do not automatically put the directory in read-only mode before export or backup operations because this would make your directory unavailable for updates. However, with multi-master replication, this might not be a problem.
2.2.2.1.1. Making a Database Read-Only Using the Console
  1. In the Directory Server Console, select the Configuration tab.
  2. Expand Data in the left pane. Expand the suffix containing the database to put in read-only mode.
  3. Select the database to put into read-only mode.
  4. Select the Database Settings tab in the right pane.
  5. Select the database is read-only check box.
The change takes effect immediately.
Before importing or restoring the database, ensure that the databases affected by the operation are not in read-only mode.
To disable read-only mode, open the database up in the Directory Server Console again and uncheck the database is read-only check box.
2.2.2.1.2. Making a Database Read-Only from the Command Line
To manually place a database into read-only mode:
  1. Run ldapmodify.
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
  2. Change the read-only attribute to on
    dn: cn=database_name,cn=ldbm database,cn=plugins,cn=config
    changetype: modify
    replace: nsslapd-readonly
    nsslapd-readonly: on

Note

By default, the name of the database created at installation time is userRoot.
2.2.2.1.3. Placing the Entire Directory Server in Read-Only Mode
If the Directory Server maintains more than one database and all databases need to be placed in read-only mode, this can be done in a single operation.

Warning

This operation also makes the Directory Server configuration read-only; therefore, you cannot update the server configuration, enable or disable plug-ins, or even restart the Directory Server while it is in read-only mode. Once read-only mode is enabled, it cannot cannot be undone from the Console; you must modify the configuration files.

Note

If Directory Server contains replicas, do not use read-only mode because it will disable replication.
To put the Directory Server in read-only mode:
  1. In the Directory Server Console, select the Configuration tab, and then select the top entry in the navigation tree in the left pane.
  2. Select the Settings tab in the right pane.
  3. Select the Make Entire Server Read-Only check box.
  4. Click Save, and then restart the server.

2.2.2.2. Deleting a Database

Deleting a database deletes the configuration information and entries for that database only, not the physical database itself.
  1. In the Directory Server Console, select the Configuration tab.
  2. Expand the Data folder, and then select the suffix.
  3. Select the database to delete.
  4. Right-click the database and select Delete from the pop-up menu.
  5. Confirm that the database should be deleted in the Delete Database dialog box.

2.2.2.3. Changing the Transaction Log Directory

The transaction log enables Directory Server to recover the database, after an instance shut down unexpectedly. In certain situations, administrators want to change the path to the transaction logs. For example, to store them on a different physical disk than the Directory Server database.

Note

To achieve higher performance, mount a faster disk to the directory that contains the transaction logs, instead of changing the location. For details, see the corresponding section in the Red Hat Directory Server Performance Tuning Guide.
To change the location of the transaction log directory:
  1. Stop the Directory Server instance:
    # systemctl stop dirsrv@instance_name
  2. Create a new location for the transaction logs. For example:
    # mkdir -p /srv/dirsrv/instance_name/db/
  3. Set permissions to enable only Directory Server to access the directory:
    # chown dirsrv:dirsrv /srv/dirsrv/instance_name/db/
    # chmod 770 /srv/dirsrv/instance_name/db/
  4. Remove all __db.* files from the previous transaction log directory. For example:
    # rm /var/lib/dirsrv/slapd-instance_name/db/__db.*
  5. Move all log.* files from the previous to the new transaction log directory. For example:
    # mv /var/lib/dirsrv/slapd-instance_name/db/log.* \
         /srv/dirsrv/instance_name/db/
  6. If SELinux is running in enforcing mode, set the dirsrv_var_lib_t context on the directory:
    # semanage fcontext -a -t dirsrv_var_lib_t /srv/dirsrv/instance_name/db/
    # restorecon -Rv /srv/dirsrv/instance_name/db/
  7. Edit the /etc/dirsrv/slapd-instance_name/dse.ldif file, and update the nsslapd-db-logdirectory parameter under the cn=config,cn=ldbm database,cn=plugins,cn=config entry. For example:
    dn: cn=config,cn=ldbm database,cn=plugins,cn=config
    ...
    nsslapd-db-logdirectory: /srv/dirsrv/instance_name/db/
  8. Start the instance:
    # systemctl start dirsrv@instance_name

2.5. Using Referrals

Referrals tell client applications which server to contact for a specific piece of information. This redirection occurs when a client application requests a directory entry that does not exist on the local server or when a database has been taken off-line for maintenance. This section contains the following information about referrals:
For conceptual information on how to use referrals in the directory, see the Red Hat Directory Server Deployment Guide.

2.5.1. Starting the Server in Referral Mode

Referrals are used to redirect client applications to another server while the current server is unavailable or when the client requests information that is not held on the current server. For example, starting Directory Server in referral mode while there are configuration changes being made to the Directory Server will refer all clients to another supplier while that server is unavailable. Starting the Directory Server in referral mode is done with the refer command.
Run nsslapd with the refer option.
# ns-slapd refer -D /etc/dirsrv/slapd-instance_name [-p port] -r referral_url
  • /etc/dirsrv/slapd-instance_name/ is the directory where the Directory Server configuration files are. This is the default location on Red Hat Enterprise Linux 7.
  • port is the optional port number of the Directory Server to start in referral mode.
  • referral_url is the referral returned to clients. The format of an LDAP URL is covered in Appendix C, LDAP URLs.

2.5.2. Setting Default Referrals

Default referrals are returned to client applications that submit operations on a DN not contained within any of the suffixes maintained by the directory. The following procedures describes setting a default referral for the directory using the console and the command-line utilities.

2.5.2.1. Setting a Default Referral Using the Console

  1. In the Directory Server Console, select the Configuration tab.
  2. Select the top entry in the navigation tree in the left pane.
  3. Select the Settings tab in the right pane.
  4. Enter an LDAP URL for the referral.
    Enter multiple referral URLs separated by spaces and in quotes:
    "ldap://dir1.example.com:389/dc=example,dc=com" "ldap://dir2.example.com/"
    For more information about LDAP URLs, see Appendix C, LDAP URLs.

2.5.2.2. Setting a Default Referral from the Command Line

ldapmodify can add a default referral to the cn=config entry in the directory's configuration file. For example, to add a new default referral from one Directory Server, dir1.example.com, to a server named dir2.example.com, add a new line to the cn=config entry.
  1. Run the ldapmodify utility and add the default referral to the dir2.example.com server:
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn: cn=config
    changetype: modify
    replace: nsslapd-referral
    nsslapd-referral: ldap://dir2.example.com/
After adding the default referral to the cn=config entry of the directory, the directory will return the default referral in response to requests made by client applications. The Directory Server does not need to be restarted.

2.5.3. Creating Smart Referrals

Smart referrals map a directory entry or directory tree to a specific LDAP URL. Using smart referrals, client applications can be referred to a specific server or a specific entry on a specific server.
For example, a client application requests the directory entry uid=jdoe,ou=people,dc=example,dc=com. A smart referral is returned to the client that points to the entry cn=john doe,o=people,l=europe,dc=example,dc=com on the server directory.europe.example.com.
The way the directory uses smart referrals conforms to the standard specified in RFC 2251 section 4.1.11. The RFC can be downloaded at http://www.ietf.org/rfc/rfc2251.txt.

2.5.3.1. Creating Smart Referrals Using the Directory Server Console

  1. In the Directory Server Console, select the Directory tab.
  2. Browse through the tree in the left navigation pane, and select the entry for which to add the referral.
  3. Right-click the entry, and select Set Smart Referrals.
  4. Select the Enable Smart Referral check box. (Unchecking the option removes all smart referrals from the entry and deletes the referral object class from the entry.)
  5. In the Enter a new Smart Referral field, enter a referral in the LDAP URL format, and then click Add. The LDAP URL must be in the following format:
    ldap://server:port/[optional_dn]
    server can be the host name, IPv4 address, or IPv6 address for the server. optional_dn is the explicit DN for the server to return to the requesting client application.
    Construct opens a wizard to direct the process of adding a referral.
    The Smart Referral List lists the referrals currently in place for the selected entry. The entire list of referrals is returned to client applications in response to a request with the Return Referrals for All Operations or Return Referrals for Update Operations options in the Suffix Settings tab, which is available under the Configuration tab.
    To modify the list, click Edit to edit the selected referral or Delete to delete the selected referral.
  6. To set the referral to use different authentication credentials, click Authentication, and specify the appropriate DN and password. This authentication remains valid only until the Console is closed; then it is reset to the same authentication used to log into the Console.

2.5.3.2. Creating Smart Referrals from the Command Line

Use the ldapmodify command-line utility to create smart referrals from the command line.
To create a smart referral, create the relevant directory entry, and add the referral object class. This object class allows a single attribute, ref. The ref attribute must contain an LDAP URL.
For example, add the following to return a smart referral for an existing entry, uid=jdoe:
dn: uid=jdoe,ou=people,dc=example,dc=com
objectclass: referral
ref: ldap://directory.europe.example.com/cn=john%20doe,ou=people,l=europe,dc=example,dc=com

Note

Any information after a space in an LDAP URL is ignored by the server. For this reason, use %20 instead of spaces in any LDAP URL used as a referral.
To add the entry uid=jdoe,ou=people,dc=example,dc=com with a referral to directory.europe.example.com, include the following in the LDIF file before importing:
dn: uid=jdoe,ou=people,dc=example,dc=com
objectclass: top
objectclass: person
objectclass: organizationalPerson
objectclass: inetOrgPerson
objectclass: referral
cn: john doe
sn: doe
uid: jdoe
ref: ldap://directory.europe.example.com/cn=john%20doe,ou=people,l=europe,dc=example,dc=com
Use the -M option with ldapmodify when there is already a referral in the DN path. For more information on smart referrals, see the Red Hat Directory Server Deployment Guide.

2.5.4. Creating Suffix Referrals

The following procedure describes creating a referral in a suffix. This means that the suffix processes operations using a referral rather than a database or database link.

Warning

When a suffix is configured to return referrals, the ACIs contained by the database associated with the suffix are ignored.

2.5.4.1. Creating Suffix Referrals Using the Console

Referrals can be used to point a client application temporarily to a different server. For example, adding a referral to a suffix so that the suffix points to a different server allows the database associated with the suffix is taken off-line for maintenance without affecting the users of the Directory Server database.
To set referrals in a suffix:
  1. In the Directory Server Console, select the Configuration tab.
  2. Under Data in the left pane, select the suffix for which to add a referral.
  3. Click the Suffix Settings tab, and select the Return Referrals for ... Operations radio button.
    Selecting Return Referrals for Update Operations means that the directory redirects only update and write requests to a read-only database. For example, there may be a local copy of directory data, and that data should be available for searches but not for updates, so it is replicated across several servers. Enabling referrals for that Directory Server only for update requests means that when a client asks to update an entry, the client is referred to the server that owns the data, where the modification request can proceed.
  4. Click the Referrals tab. Enter an LDAP URL in the[1] in the Enter a new referral field, or click Construct to create an LDAP URL.
  5. Click Add to add the referral to the list.
    You can enter multiple referrals. The directory returns the entire list of referrals in response to requests from client applications.

2.5.4.2. Creating Suffix Referrals from the Command Line

Add a suffix referral to the root or sub suffix entry in the directory configuration file under the cn=mapping tree,cn=config branch.
Run ldapmodify and add a suffix referral to the ou=people,dc=example,dc=com root suffix:
# ldapmodify -a -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: cn=ou=people,dc=example,dc=com,cn=mapping tree,cn=config
changetype: add
objectclass: extensibleObject
objectclass: nsMappingTree
nsslapd-state: referral
nsslapd-referral: ldap://zanzibar.com/
The nsslapd-state attribute is set to referral, meaning that a referral is returned for requests made to this suffix. The nsslapd-referral attribute contains the LDAP URL of the referral returned by the suffix, in this case a referral to the zanzibar.com server.
The nsslapd-state attribute can also be set to referral on update. This means that the database is used for all operations except update requests. When a client application makes an update request to a suffix set to referral on update, the client receives a referral.
For more information about the suffix configuration attributes, see Section 2.1.1.3, “Creating Root and Sub Suffixes using the Command Line”.


[] Unlike the standard LDAP URL format, the URL of the remote server does not specify a suffix. It has the form ldap://server:port/, where server can be the host name, IPv4 address, or IPv6 address.
[1] Appendix C, LDAP URLs has more information about the structure of LDAP URLs.

Chapter 3. Managing Directory Entries

This chapter discusses how to use the Directory Server Console and the ldapmodify and ldapdelete command-line utilities to modify the contents of your directory.
Entries stored in Active Directory can be added to the Directory Server through Windows Sync; see Chapter 16, Synchronizing Red Hat Directory Server with Microsoft Active Directory for more information on adding or modifying synchronized entries through Windows User Sync.

3.1. Managing Entries Using the Command Line

To perform LDAP operations using the command line, install the openldap-clients package. The utilities installed by this package enable you to:
  • Add new entries
  • Add new attributes to existing entries
  • Update existing entries and attributes
  • Delete entries and attributes from entries
  • Perform bulk operations
To install the openldap-clients package:
# yum install openldap-clients

Note

To perform LDAP operations, you need the appropriate permissions. For details about access control, see Chapter 18, Managing Access Control.

3.1.1. Providing Input to the ldapadd, ldapmodify, and ldapdelete Utilities

When you add, update, or delete entries or attributes in your directory, you can either use the interactive mode of the utilities to enter LDAP Data Interchange Format (LDIF) statements or pass an LDIF file to them.
For further details about LDIF, see Section B.1, “About the LDIF File Format”.

3.1.1.1. Providing Input Using the Interactive Mode

In the interactive mode, the ldapadd, ldapmodify, and ldapdelete utilities read the input from the command line. To exit the interactive mode, press the Ctrl+D (^D) key combination to send the End Of File (EOF) escape sequence.
In interactive mode, the utility sends the statements to the LDAP server when you press Enter twice or when you send the EOF sequence.
Use the interactive mode:
  • To enter LDIF statements without creating a file:

    Example 3.1. Using the ldapmodify Interactive Mode to Enter LDIF Statements

    The following example starts ldapmodify in interactive mode, deletes the telephoneNumber attribute, and adds the manager attribute with the cn=manager_name,ou=people,dc=example,dc=com value to the uid=user,ou=people,dc=example,dc=com entry. Press Ctrl+D after the last statement to exit the interactive mode.
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn: uid=user,ou=people,dc=example,dc=com
    changetype: modify
    delete: telephoneNumber
    -
    add: manager
    manager: cn=manager_name,ou=people,dc=example,dc=com
    ^D
  • To redirect LDIF statements, outputted by another command, to Directory Server:

    Example 3.2. Using the ldapmodify Interactive Mode with Redirected Content

    The following example redirects the output of the command_that_outputs_LDIF command to ldapmodify. The interactive mode exits automatically after the redirected command exits.
    # command_that_outputs_LDIF | ldapmodify -D "cn=Directory Manager" \
         -W -p 389 -h server.example.com -x

3.1.1.2. Providing Input Using an LDIF File

In the interactive mode, the ldapadd, ldapmodify, and ldapdelete utilities read the LDIF statements from a file. Use this mode to send a larger number of LDIF statements to Directory Server.

Example 3.3. Passing a File with LDIF Statements to ldapmodify

  1. Create a file with the LDIF statements. For example, create the ~/example.ldif file with the following statements:
    dn: uid=user,ou=people,dc=example,dc=com
    changetype: modify
    delete: telephoneNumber
    -
    add: manager
    manager: cn=manager_name,ou=people,dc=example,dc=com
    This example deletes the telephoneNumber attribute and to adds the manager attribute with the cn=manager_name,ou=people,dc=example,dc=com value to the uid=user,ou=people,dc=example,dc=com entry
  2. Pass the file to the ldapmodify command using the -f file_name option:
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x \
         -f ~/example.ldif

3.1.2. The Continuous Operation Mode

If you send multiple LDIF statements to Directory Server and one operation fails, the process stops. However, entries processed before the error occurred were successfully added, modified, or deleted.
To ignore errors and continue processing further LDIF statements in a batch, pass the -c option to ldapadd and ldapmodify. For example:
# ldpamodify -c -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

3.1.3. Adding an Entry

To add a new entry to the directory, use the ldapadd or ldapmodify utility. Note that ldapadd is a symbolic link to /bin/ldapmodify. Therefore, ldapadd performs the same operation as ldapmodify -a.

Note

You can only add a new directory entry, if the parent entry already exists. For example, you cannot add the cn=user,ou=people,dc=example,dc=com entry, if the ou=people,dc=example,dc=com parent entry does not exist.

3.1.3.1. Adding an Entry Using ldapadd

To use the ldapadd utility to add, for example, the cn=user,ou=people,dc=example,dc=com user entry:
# ldapadd -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: uid=user,ou=People,dc=example,dc=com
uid: user
givenName: given_name
objectClass: top
objectClass: person
objectClass: organizationalPerson
objectClass: inetorgperson
sn: surname
cn: user

Note

Running ldapadd automatically performs a changetype: add operation. Therefore, you do not need to specify changetype: add in the LDIF statement.
For further details on the parameters used in the command, see the ldapadd(1) man page.

3.1.3.2. Adding an Entry Using ldapmodify

To use the ldapmodify utility to add, for example, the cn=user,ou=people,dc=example,dc=com user entry:
# ldapmodify -a -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: uid=user,ou=People,dc=example,dc=com
uid: user
givenName: given_name
objectClass: top
objectClass: person
objectClass: organizationalPerson
objectClass: inetorgperson
sn: surname
cn: user

Note

When passing the -a option to the ldapmodify command, the utility automatically performs a changetype: add operation. Therefore, you do not need to specify changetype: add in the LDIF statement.
For further details on the parameters used in the command, see the ldapmodify(1) man page.

3.1.3.3. Creating a Root Entry

To create the root entry of a database suffix, such as dc=example,dc=com, bind as the cn=Directory Manager user and add the entry.
The DN corresponds to the DN of the root or sub-suffix of the database.
For example, to add the dc=example,dc=com suffix:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: dc=example,dc=com
changetype: add
objectClass: top
objectClass: domain
dc: example

Note

You can add root objects only if you have one database per suffix. If you create a suffix that is stored in several databases, you must use the ldif2db utility with the -n back_end option to set the database that will hold the new entries. For details, see Section 6.1.4, “Importing from the Command Line”.

3.1.4. Updating a Directory Entry

When you modify a directory entry, use the changetype: modify statement. Depending on the change operation, you can add, change, or delete attributes from the entry.
Use the ldapmodify utility to send the LDIF statements to Directory Server. For example, in interactive mode:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
For further details on the parameters used in ldapmodify commands, see the ldapmodify(1) man page.

3.1.4.1. Adding Attributes to an Entry

To add an attribute to an entry, use the add operation.
For example, to add the telephoneNumber attribute with the 555-1234567 value to the uid=user,dc=people,dc=example,dc=com entry:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: uid=user,dc=people,dc=example,dc=com
changetype: modify
add: telephoneNumber
telephoneNumber: 555-1234567
If an attribute is multi-valued, you can specify the attribute name multiple times to add all the values in a single operation. For example, to add two telephoneNumber attributes at once to the uid=user,dc=people,dc=example,dc=com:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: uid=user,dc=people,dc=example,dc=com
changetype: modify
add: telephoneNumber
telephoneNumber: 555-1234567
telephoneNumber: 555-7654321

3.1.4.2. Updating an Attribute's Value

The procedure for updating an attribute's value depends on if the attribute is single-valued or multi-valued.

Updating a Single-value Attribute

When updating a single-value attribute, use the replace operation to override the existing value. The following command updates the manager attribute of the uid=user,dc=people,dc=example,dc=com entry:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: uid=user,dc=people,dc=example,dc=com
changetype: modify
replace: manager
manager: uid=manager_name,dc=people,dc=example,dc=com

Updating a Specific Value of a Multi-value Attribute

To update a specific value of a multi-value attribute, you must first delete the entry you want to replace, and then add the new value. The following command updates only the telephoneNumber attribute that is currently set to 555-1234567 in the uid=user,dc=people,dc=example,dc=com entry:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: uid=user,dc=people,dc=example,dc=com
changetype: modify
delete: telephoneNumber
telephoneNumber: 555-1234567
-
add: telephoneNumber
telephoneNumber: 555-9876543

3.1.4.3. Deleting Attributes from an Entry

To delete an attribute from an entry, use the delete operation.

Deleting an Attribute

For example, to delete the manager attribute from the uid=user,dc=people,dc=example,dc=com entry:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: uid=user,dc=people,dc=example,dc=com
changetype: modify
delete: manager

Note

If the attribute contains multiple values, this operation deletes all of them.

Deleting a Specific Value of a Multi-value Attribute

If you want to delete a specific value from a multi-value attribute, list the attribute and its value in the LDIF statement. For example, to delete only the telephoneNumber attribute that is set to 555-1234567 from the uid=user,dc=people,dc=example,dc=com entry:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: uid=user,dc=people,dc=example,dc=com
changetype: modify
delete: telephoneNumber
telephoneNumber: 555-1234567

3.1.5. Deleting an Entry

Deleting an entry removes the entry from the directory.

Note

You can only delete entries that have no child entries. For example, you cannot delete the ou=People,dc=example,dc=com entry, if the uid=user,ou=People,dc=example,dc=com entry still exists.

3.1.5.1. Deleting an Entry Using ldapdelete

The ldapdelete utility enables you to delete one or multiple entries. For example, to delete the uid=user,ou=People,dc=example,dc=com entry:
# ldapdelete -D "cn=Directory Manager" -W -p 389 -h server.example.com -x "uid=user,ou=People,dc=example,dc=com"
To delete multiple entries in one operation, append them to the command. For example:
# ldapdelete -D "cn=Directory Manager" -W -p 389 -h server.example.com -x \
     "uid=user1,ou=People,dc=example,dc=com" \
     "uid=user2,ou=People,dc=example,dc=com"
For further details on the parameters used, see the ldapdelete(1) man page.

3.1.5.2. Deleting an Entry Using ldapmodify

To delete an entry using the ldapmodify utility, use the changetype: delete operation. For example, to delete the uid=user,ou=People,dc=example,dc=com entry:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: uid=user,dc=people,dc=example,dc=com
changetype: delete

3.1.6. Renaming and Moving an Entry

Use the ldapmodify utility to send the LDIF statements to Directory Server when you rename an entry. For example, in interactive mode:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
For further details on the parameters used in ldapmodify commands, see the ldapmodify(1) man page.

Note

Use the moddn Access Control List (ACL) to grant permissions to move entries. For details, see Section 18.11.2.1, “Targeting Source and Destination DNs”.

3.1.6.1. Types of Rename Operations

The following rename operations exist:
Renaming an Entry
If you rename a entry, the modrdn operation changes the Relative Distinguished Name (RDN) of the entry:
Renaming a Subentry
For subtree entries, the modrdn operation renames the subtree and also the DN components of child entries:
Note that for large subtrees, this process can take a lot of time and resources.
Moving an Entry to a New Parent
A similar action to renaming a subtree is moving an entry from one subtree to another. This is an expanded type of the modrdn operation, which simultaneously renames the entry and sets a newSuperior attribute which moves the entry from one parent to another:

3.1.6.2. Considerations for Renaming Entries

Keep the following in mind when performing rename operations:
  • You cannot rename the root suffix.
  • Subtree rename operations have minimal effect on replication. Replication agreements are applied to an entire database, not a subtree within the database. Therefore, a subtree rename operation does not require reconfiguring a replication agreement. All name changes after a subtree rename operation are replicated as normal.
  • Renaming a subtree might require any synchronization agreements to be reconfigured. Synchronization agreements are set at the suffix or subtree level. Therefore, renaming a subtree might break synchronization.
  • Renaming a subtree requires that any subtree-level Access Control Instructions (ACI) set for the subtree be reconfigured manually, as well as any entry-level ACIs set for child entries of the subtree.
  • Trying to change the component of a subtree, such as moving from ou to dc, might fail with a schema violation. For example, the organizationalUnit object class requires the ou attribute. If that attribute is removed as part of renaming the subtree, the operation fails.
  • If you move a group, the MemberOf plug-in automatically updates the memberOf attributes. However, if you move a subtree that contain groups, you must manually create a task in the cn=memberof task entry or use the fixup-memberof.pl to update the related memberOf attributes.
    For details about cleaning up memberOf attribute references, see Section 8.1.4.7, “Synchronizing memberOf Values”.

3.1.6.3. The deleteOldRDN Parameter

When you rename an entry, the deleteOldRDN parameter controls whether the old RDN will be deleted or retained.
deleteOldRDN: 0
The existing RDN is retained as a value in the new entry. The resulting entry contains two cn attributes: one with the old and one with the new common name (CN).
For example, the following attributes belong to a group that was renamed from cn=old_group,dc=example,dc=com to cn=new_group,dc=example,dc=com with the deleteOldRDN: 0 parameter set.
dn: cn=new_group,ou=Groups,dc=example,dc=com
objectClass: top
objectClass: groupOfUniqueNames
cn: old_group
cn: new_group
deleteOldRDN: 1
Directory Server deletes the old entry and creates a new entry using the new RDN. The new entry only contains the cn attribute of the new entry.
For example, the following group was renamed to cn=new_group,dc=example,dc=com with the deleteOldRDN: 1 parameter set:
dn: cn=new_group,ou=Groups,dc=example,dc=com
objectClass: top
objectClass: groupofuniquenames
cn: new_group

3.1.6.4. Renaming an Entry or Subtree

To rename an entry or subtree, use the changetype: modrdn operation and set the new RDN in the newrdn attribute.
For example, to rename the cn=old_group,ou=Groups,dc=example,dc=com entry to cn=new_group,ou=Groups,dc=example,dc=com:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: cn=old_group,ou=Groups,dc=example,dc=com
changetype: modrdn
newrdn: cn=new_group
deleteOldRDN: 1
For details about the deleteOldRDN, see Section 3.1.6.3, “The deleteOldRDN Parameter”.

3.1.6.5. Moving an Entry to a New Parent

To move an entry to a new parent, use the changetype: modrdn operation and set the following to attributes:
newrdn
Sets the RDN of the moved entry. You must set this entry, even if the RDN remains the same.
newSuperior
Sets the DN of the new parent entry.
For example, to move the uid=user entry from ou=Engineering,ou=People,dc=example,dc=com to ou=Marketing,ou=People,dc=example,dc=com:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: uid=user,ou=Engineering,ou=People,dc=example,dc=com
changetype: modrdn
newrdn: uid=user
newSuperior= uid=user,ou=Marketing,ou=People,dc=example,dc=com
deleteOldRDN: 1
For details about the deleteOldRDN, see Section 3.1.6.3, “The deleteOldRDN Parameter”.

3.1.7. Using Special Characters

When using the command line, enclose characters that have a special meaning to the command-line interpreter, such as space ( ), asterisk (*), or backslash (\), with quotation marks. Depending on the command-line interpreter, use single or double quotation marks.
For example, to authenticate as the cn=Directory Manager user, enclose the user's DN in quotation marks:
# ldapmodify -a -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
Additionally, if a DN contains a comma in a component, escape it using a backslash. For example, to authenticate as the uid=user,ou=People,dc=example.com Chicago, IL user:
# ldapmodify -a -D "cn=uid=user,ou=People,dc=example.com Chicago\, IL" \
     -W -p 389 -h server.example.com -x

3.1.8. Using Binary Attributes

Certain attributes support binary values, such as the jpegPhoto attribute. When you add or update such an attribute, the utility reads the value for the attribute from a file. To add or update such an attribute, you can use the -b binary option of the ldapadd or ldapmodify utility, or the standard LDIF notation.
For example, to add the jpegPhoto attribute to the uid=user,ou=People,dc=example,dc=com entry, and read the value for the attribute from the ~/photo.jpg file:
  • Using the binary option: Pass the -b option to the command, and set the binary attribute to the path of the file:
    # ldapmodify -b -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn: uid=user,ou=People,dc=example,dc=com
    changetype: modify
    add: jpegPhoto
    jpegPhoto: ~/photo.jpg
  • Using standard LDIF notation: Set the attribute's value to the path of the file using the < file:path_to_file syntax:
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn: uid=user,ou=People,dc=example,dc=com
    changetype: modify
    add: jpegPhoto
    jpegPhoto: < ~/photo.jpg

3.1.9. Updating an Entry in an Internationalized Directory

To use attribute values with languages other than English, associate the attribute's value with a language tag.
When using ldapmodify to update an attribute that has a language tag set, you must match the value and language tag exactly or the operation will fail.
For example, to modify an attribute value that has the lang-fr language tag set, include the tag in the modify operation:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: uid=user,ou=People,dc=example,dc=com
changetype: modify
replace: homePostalAddress;lang-fr
homePostalAddress;lang-fr: 34 rue de Seine

3.2. Managing Entries Using the Directory Console

You can use the Directory tab and the Property Editor on the Directory Server Console to add, modify, or delete entries individually.
To add several entries simultaneously, use the command-line utilities described in Section 3.1, “Managing Entries Using the Command Line”.

Note

You cannot modify your directory unless the appropriate access control rules have been set. For information on creating access control rules for your directory, see Chapter 18, Managing Access Control.

3.2.1. Creating a Root Entry

Each time a new database is created, it is associated with the suffix that will be stored in the database. The directory entry representing that suffix is not automatically created.
To create a root entry for a database:
  1. In the Directory Server Console, select the Configuration tab.
  2. Right-click on the Data entry in the left menu, and select New Root Suffix from the menu.
  3. Fill in the new suffix and database information.
  4. In the Directory tab, right-click the top object representing the Directory Server, and choose New Root Object.
    The secondary menu under New Root Object displays the new suffixes without a corresponding directory entry. Choose the suffix corresponding to the entry to create.
  5. In the New Object window, select the object class corresponding to the new entry.
    The object class must contain the attribute used to name the suffix. For example, if the entry corresponds to the suffix ou=people,dc=example,dc=com, then choose the organizationalUnit object class or another object class that allows the ou attribute.
  6. Click OK in the New Object window.
The Property Editor for the new entry opens. You can either accept the current values by clicking OK or modify the entry, as explained in Section 3.2.3, “Modifying Directory Entries”.

3.2.2. Creating Directory Entries

Directory Server Console offers predefined templates, with preset forms, for new directory entries. Table 3.1, “Entry Templates and Corresponding Object Classes” shows what type of object class is used for each template.

Table 3.1. Entry Templates and Corresponding Object Classes

Template Object Class
User inetOrgPerson
Group groupOfUniqueNames
Organizational Unit organizationalUnit
Role nsRoleDefinition
Class of Service cosSuperDefinition
Another type, Other allows any kind of entry to be created by allowing users to select the specific object classes and attributes to apply.
  1. In the Directory Server Console, select the Directory tab.
  2. In the left pane, right-click the main entry to add the new entry, and select the type of entry: User, Group, Organizational Unit, Role, Class of Service, or Other.
  3. If the new entry type was Other, then a list of object classes opens. Select an object class from the list to define the new entry.
  4. Supply a value for all the listed attributes. Required attributes are marked with an asterisk (*).
  5. To display the full list of attributes available for the object class (entry type), click the Advanced button.
    In the Property Editor, select any additional attributes, and fill in the attribute values.
  6. Click OK to save the entry. The new entry is listed in the right pane.

3.2.3. Modifying Directory Entries

Modifying directory entries in Directory Server Console uses a dialog window called the Property Editor. The Property Editor contains the list of object classes and attributes belonging to an entry and can be used to edit the object classes and attributes belonging to that entry by adding and removing object classes, attributes and attribute values, and attribute subtypes.
The Property Editor can be opened in several ways:
  • From the Directory tab, by right-clicking an entry, and selecting Advanced Properties from the pop-up menu.
  • From the Directory tab, by double-clicking an entry and clicking the Advanced button
  • From the Create... new entry forms, by clicking the Advanced button
  • From the New Object window, by clicking OK

3.2.3.1. Adding or Removing an Object Class to an Entry

To add an object class to an entry:
  1. In the Directory tab of the Directory Server Console, right-click the entry to modify, and select Advanced from the pop-up menu.
  2. Select the object class field, and click Add Value.
    The Add Object Class window opens. It shows a list of object classes that can be added to the entry.
  3. Select the object class to add, and click OK.
To remove an object class from an entry, click the text box for the object class to remove, and then click Delete Value.

3.2.3.2. Adding an Attribute to an Entry

Before you can add an attribute to an entry, the entry must contain an object class that either requires or allows the attribute. See Section 3.2.3.1, “Adding or Removing an Object Class to an Entry” and Chapter 12, Managing the Directory Schema for more information.
To add an attribute to an entry:
  1. In the Directory tab of the Directory Server Console, right-click the entry to modify, and select Advanced from the pop-up menu.
  2. Click Add Attribute.
  3. Select the attribute to add from the list, and click OK.

    Note

    If the attribute you want to add is not listed, add the object class containing the attribute first, then add the attribute. See Section 3.2.3.1, “Adding or Removing an Object Class to an Entry” for instructions on adding an object class. If you do not know which object class contains the attribute you need, look up the attribute in the Red Hat Directory Server 10 Configuration, Command, and File Reference., which lists the object classes which use that attribute.
  4. Type in the value for the new attribute in the field to the right of the attribute name.
To remove the attribute and all its values from the entry, select Delete Attribute from the Edit menu.

3.2.3.3. Adding Very Large Attributes

The configuration attribute nsslapd-maxbersize sets the maximum size limit for LDAP requests. The default configuration of Directory Server sets this attribute at 2 megabytes. LDAP add or modify operations will fail when attempting to add very large attributes that result in a request that is larger than 2 megabytes. However, the limit is not applied to replication processes.
To add very large attributes, first change the setting for the nsslapd-maxbersize configuration attribute to a value larger than the largest LDAP request you will make.
When determining the value to set, consider all elements of the LDAP add and modify operations used to add the attributes, not just the single attribute. There are a number of different factors to consider, including the following:
  • The size of each attribute name in the request
  • The size of the values of each of the attributes in the request
  • The size of the DN in the request
  • Some overhead, usually 10 kilobytes
One common issue that requires increasing the nsslapd-maxbersize setting is using attributes which hold CRL values, such as certificateRevocationList, authorityRevocationList, and deltaRevocationList.
For further information about the nsslapd-maxbersize attribute, see the corresponding section in the Red Hat Directory Server Configuration, Command, and File Reference.

3.2.3.4. Adding Attribute Values

Multi-valued attributes allow multiple value for one attribute to be added to an entry.
  1. In the Directory tab of the Directory Server Console, right-click the entry to modify, and select Advanced from the pop-up menu.
  2. Select the attribute to which to add a value, and then click Add Value.
  3. Type in the new attribute value.
To remove an attribute value from an entry, click the text box of the attribute value to remove, and click Delete Value.

3.2.3.5. Adding an Attribute Subtype

A subtype allows the same entry value to be represented in different ways, such as providing a foreign-characterset version. There three different kinds of subtypes to attributes which can be added to an entry: language, binary, and pronunciation.
To add a subtype to an entry:
  1. In the Directory tab of the Directory Server Console, right-click the entry to modify, and select Properties from the pop-up menu.
  2. Click Add Attribute, and select the attribute to add from the list.
  3. Add a language subtype by selecting a value from the Language drop-down list. Add either a binary or pronunciation subtype by selecting a value from the Subtype drop-down list.
Language Subtype

Sometimes a user's name can be more accurately represented in characters of a language other than the default language. For example, a user, Noriko, has a name in Japanese and prefers that her name be represented by Japanese characters when possible. You can select Japanese as a language subtype for the givenname attribute so that other users can search for her name in Japanese as well as English. For example:

givenname;lang-ja
To specify a language subtype for an attribute, add the subtype to the attribute name as follows:
attribute;lang-subtype:attribute value
attribute is the attribute being added to the entry and subtype is the two character abbreviation for the language. The supported language subtypes are listed in Table D.1, “Supported Language Subtypes”.
Only one language subtype can be added per attribute instance in an entry. To assign multiple language subtypes, add another attribute instance to the entry, and then assign the new language subtype. For example, the following is illegal:
cn;lang-ja;lang-en-GB:value
Instead, use:
cn;lang-ja:ja-value
cn;lang-en-GB:value
Binary Subtype

Assigning the binary subtype to an attribute indicates that the attribute value is binary, such as user certificates (usercertificate;binary).

Although you can store binary data within an attribute that does not contain the binary subtype (for example, jpegphoto), the binary subtype indicates to clients that multiple variants of the attribute type may exist.
Pronunciation Subtype

Assigning the pronunciation subtype to an attribute indicates that the attribute value is a phonetic representation. The subtype is added to the attribute name as attribute;phonetic. This subtype is commonly used in combination with a language subtype for languages that have more than one alphabet, where one is a phonetic representation.

This subtype is useful with attributes that are expected to contain user names, such as cn or givenname. For example, givenname;lang-ja;phonetic indicates that the attribute value is the phonetic version of the user's Japanese name.

3.2.4. Deleting Directory Entries

  1. In the Directory Server Console, select the Directory tab.
  2. Right-click the entry to delete, and select Delete from the right-click menu.

Warning

The server deletes the entry or entries immediately. There is no way to undo the delete operation.

Chapter 4. Tracking Modifications to Directory Entries

It can be useful to track when changes are made to entries. There are two aspects of entry modifications that the Directory Server tracks:
  • Using change sequence numbers to track changes to the database. This is similar to change sequence numbers used in replication and synchronization. Every normal directory operation triggers a sequence number.
  • Assigning creation and modification information. These attributes record the names of the user who created and most recently modified an entry, as well as the timestamps of when it was created and modified.

Note

The entry USN, modify time and name, and create time and name are all operational attributes and are not returned in a regular ldapsearch. For details on running a search for operational attributes, see Section 14.5.7, “Searching for Operational Attributes”.

4.1. Tracking Modifications to the Database through Update Sequence Numbers

The USN Plug-in provides a way for LDAP clients to know that something — anything — in the database has changed.

4.1.1. An Overview of the Entry Sequence Numbers

When the USN Plug-in is enabled, update sequence numbers (USNs) are sequential numbers that are assigned to an entry whenever a write operation is performed against the entry. (Write operations include add, modify, modrdn, and delete operations. Internal database operations, like export operations, are not counted in the update sequence.) A USN counter keeps track of the most recently assigned USN.

4.1.1.1. Local and Global USNs

The USN is evaluated globally, for the entire database, not for the single entry. The USN is similar to the change sequence number for replication and synchronization, in that it simply ticks upward to track any changes in the database or directory. However, the entry USN is maintained separately from the CSNs, and USNs are not replicated.
The entry shows the change number for the last modification to that entry in the entryUSN operational attribute. (For details on running a search for operational attributes, see Section 14.5.7, “Searching for Operational Attributes”.)

Example 4.1. Example Entry USN

 dn: uid=jsmith,ou=People,dc=example,dc=com
 mail: jsmith@example.com
 uid: jsmith
 givenName: John
 objectClass: top
 objectClass: person
 objectClass: organizationalPerson
 objectClass: inetorgperson
 sn: Smith
 cn: John Smith
 userPassword: {SSHA}EfhKCI4iKl/ipZMsWlITQatz7v2lUnptxwZ/pw==
 entryusn: 1122
The USN Plug-in has two modes, local mode and global mode:
  • In local mode, each back end database has an instance of the USN Plug-in with a USN counter specific to that back end database. This is the default setting.
  • In global mode, there is a global instance of the USN Plug-in with a global USN counter that applies to changes made to the entire directory.
When the USN Plug-in is set to local mode, results are limited to the local back end database. When the USN Plug-in is set to global mode, the returned results are for the entire directory.
The root DSE shows the most recent USN assigned to any entry in the database in the lastusn attribute. When the USN Plug-in is set to local mode, so each database has its own local USN counter, the lastUSN shows both the database which assigned the USN and the USN:
lastusn;database_name:USN
For example:
lastusn;example1: 2130
lastusn;example2: 2070
In global mode, when the database uses a shared USN counter, the lastUSN attribute shows the latest USN only:
lastusn: 4200

4.1.1.2. Importing USN Entries

When entries are imported, the USN Plug-in uses the nsslapd-entryusn-import-initval attribute to check if the entry has an assigned USN. If the value of nsslapd-entryusn-import-initval is numerical, the imported entry will use this numerical value as the entry's USN. If the value of nsslapd-entryusn-import-initval is not numerical, the USN Plug-in will use the value of the lastUSN attribute and increment it by one as the USN for the imported entry.

4.1.2. Configuring the USN Plug-in

The USN Plug-in must be enabled for USNs to be recorded on entries, as described in Section 1.9.2.2, “Enabling Plug-ins in the Directory Server Console”. The plug-in can be enabled through the Directory Server Console or through the command line. For example:
# ldapmodify -D "cn=Directory Manager" -W -x
dn: cn=USN,cn=plugins,cn=config
changetype: modify
replace: nsslapd-pluginEnabled
nsslapd-pluginEnabled: on
Then restart the server to apply the changes.

4.1.3. Enabling Global USN

With the default settings, Directory Server uses unique update sequence numbers (USN) for each back end database. To enable unique USNs across all back end databases:
  1. Set the nsslapd-entryusn-global parameter to on:
    # ldapmodify -D "cn=Directory Manager" -W -x
    dn: cn=config
    changetype: modify
    replace: nsslapd-entryusn-global
    nsslapd-entryusn-global: on

4.1.4. Cleaning up USN Tombstone Entries

The USN Plug-in moves entries to tombstone entries when the entry is deleted. If replication is enabled, then separate tombstone entries are kept by both the USN and Replication Plug-ins. Both tombstone entries are deleted by the replication process, but for server performance, it can be beneficial to delete the USN tombstones before converting a server to a replica or to free memory for the server.
The usn-tombstone-cleanup.pl command deletes USN tombstone entries for a specific database back end or specific suffix. Optionally, it can delete all of tombstone entries up to a certain USN. For example:
# /usr/lib64/dirsrv/instance/usn-tombstone-cleanup.pl -D "cn=Directory Manager" -w secret -s "ou=people,dc=example,dc=com" -m 1100
Either the back end must be specified using the -n option or the suffix, using the -s option. If both are given, then the suffix in the -s option is used.
The options for usn-tombstone-cleanup.pl command are listed in Table 4.1, “usn-tombstone-cleanup.pl Options”. More details for this tool are in the Configuration, Command, and File Reference.

Table 4.1. usn-tombstone-cleanup.pl Options

Option Description
-D rootdn Gives the user DN with root permissions, such as Directory Manager. The default is the DN of the Directory Manager, which is read from the nsslapd-root attribute under cn=config.
-m maximum_USN Sets the upper bound for entries to delete. All tombstone entries with an entryUSN value up to the specified maximum (inclusive) are deleted, but not past that USN value. If no maximum USN value is set, then all back end tombstone entries are deleted.
-n backendInstance Gives the name of the database containing the entries to clean (delete).
-s suffix Gives the name of the suffix containing the entries to clean (delete).
-w password The password associated with the user DN.

4.2. Tracking Entry Modifications through Operational Attributes

Using the default settings, Directory Server tracks the following operational attributes for every entry:
  • creatorsName: The distinguished name (DN) of the user who initially created the entry.
  • createTimestamp: The times stamp in Greenwich Mean Time (GMT) format when the entry was created.
  • modifiersName: The distinguished name of the user who last modified the entry.
  • modifyTimestamp: The time stamp in the GMT format for when the entry was last modified.
Note that operational attributes are not returned in default searches. You must explicitly request these attributes in queries. For details, see Section 14.5.7, “Searching for Operational Attributes”.

Important

Red Hat recommends not disabling tracking these operational attributes. If disabled, entries do not get a unique ID assigned in the nsUniqueID attribute and replication does not work.

4.2.2. How to Enable Tracking Of Modifications Using the Command Line

Modification tracking is enabled by default, and Red Hat recommends not disabling this feature. To re-enable tracking of entry modifications using the command line:
  1. Set the nsslapd-lastmod to on:
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn: cn=config
    nsslapd-lastmod: on
  2. Optionally, to regenerate the missing nsUniqueID attributes:
    1. Export the database to an LDAP Data Interchange Format (LDIF) file. See Section 6.2.3, “Exporting a Database to LDIF Using the Command Line”.
    2. Import the database from the LDIF file. See Section 6.1.4, “Importing from the Command Line”.

4.2.3. How to Enable Tracking Of Modifications Using the Console

Modification tracking is enabled by default, and Red Hat recommends not disabling this feature. To re-enable tracking of entry modifications using the Console:
  1. Open the Directory Server Console. See Section 1.3.1, “Opening the Directory Server Console”.
  2. On the Configuration tab, select the server name.
  3. On the Settings tab, select the Track Entry Modification Times check box.
  4. Optionally, to regenerate the missing nsUniqueID attributes:
    1. Export the database to an LDAP Data Interchange Format (LDIF) file. See Section 6.2.3, “Exporting a Database to LDIF Using the Command Line”.
    2. Import the database from the LDIF file. See Section 6.1.4, “Importing from the Command Line”.

4.3. Tracking the Bind DN for Plug-in Initiated Updates

One change to an entry can trigger other, automatic changes across the directory tree. When a user is deleted, for example, that user is automatically removed from any groups it belonged to by the Referential Integrity Postoperation plug-in.
The initial action is shown in the entry as being performed by whatever user account is bound to the server, but all related updates (by default) are shown as being performed by the plug-in, with no information about which user initiated that update. For example, using the MemberOf Plug-in to update user entries with group membership, the update to the group account is shown as being performed by the bound user, while the edit to the user entry is shown as being performed by the MemberOf Plug-in:
dn: cn=my_group,ou=groups,dc=example,dc=com
modifiersname: uid=jsmith,ou=people,dc=example,dc=com

dn: uid=bjensen,ou=people,dc=example,dc=com
modifiersname: cn=memberOf plugin,cn=plugins,cn=config
The nsslapd-plugin-binddn-tracking attribute allows the server to track which user originated an update operation, as well as the internal plug-in which actually performed it. The bound user is shown in the modifiersname and creatorsname operational attributes, while the plug-in which performed it is shown in the internalModifiersname and internalCreatorsname operational attributes. For example:
dn: uid=bjensen,ou=people,dc=example,dc=com
modifiersname: uid=jsmith,ou=people,dc=example,dc=com
internalModifiersname: cn=memberOf plugin,cn=plugins,cn=config
The nsslapd-plugin-binddn-tracking attribute tracks and maintains the relationship between the bound user and any updates performed for that connection.

Note

The internalModifiersname and internalCreatorsname attributes always show a plug-in as the identity. This plug-in could be an additional plug-in, such as the MemberOf Plug-in. If the change is made by the core Directory Server, then the plug-in is the database plug-in, cn=ldbm database,cn=plugins,cn=config.
The nsslapd-plugin-binddn-tracking attribute is disabled by default. To allow the server to track operations based on bind DN, enable that attribute using ldapmodify:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: cn=config
changetype: modify
replace: nsslapd-plugin-binddn-tracking
nsslapd-plugin-binddn-tracking: on

4.4. Tracking Password Change Times

Password change operations are normally treated as any other modification to an entry, so the update time is recorded in the lastModified operational attribute. However, there can be times when the time of the last password change needs to be recorded separately, to make it easier to update passwords in Active Directory synchronization or to connect with other LDAP clients.
The passwordTrackUpdateTime attribute within the password policy tells the server to record a timestamp for the last time that the password was updated for an entry. The password change time itself is stored as an operational attribute on the user entry, pwdUpdateTime (which is separate from the modifyTimestamp or lastModified operational attributes).
The passwordTrackUpdateTime attribute can be set as part of the global password policy or on a subtree or user-level policy, depending on what clients need to access the password change time. Setting password policies is described in Section 19.4, “Managing the Password Policy”.

Chapter 5. Maintaining Referential Integrity

Referential Integrity is a database mechanism that ensures relationships between related entries are maintained. In the Directory Server, the Referential Integrity can be used to ensure that an update to one entry in the directory is correctly reflected in any other entries that reference to the updated entry.
For example, if a user's entry is removed from the directory and Referential Integrity is enabled, the server also removes the user from any groups of which the user is a member. If Referential Integrity is not enabled, the user remains a member of the group until manually removed by the administrator. This is an important feature if you are integrating the Directory Server with other products that rely on the directory for user and group management.

5.1. How Referential Integrity Works

When the Referential Integrity Postoperation plug-in is enabled, it performs integrity updates on specified attributes immediately after a delete or rename operation. By default, the Referential Integrity Postoperation plug-in is disabled.

Note

Enable the Referential Integrity Postoperation plug-in only on one supplier replica in a multi-master replication environment, because the operations generated by the plug-in will be replicated. If you enable the plug-in on multiple masters, the servers have to manage and reapply already performed operations.
When a user or group entry is deleted, updated, renamed, or moved within the directory, the operation is logged to the Referential Integrity log file. For the distinguished names (DN) in the log file, Directory Server searches and updates in intervals the attributes set in the plug-in configuration:
  • For entries, marked in the log file as deleted, the corresponding attribute in the directory is deleted.
  • For entries, marked in the log file as updated, the corresponding attribute in the directory is updated.
  • For entries, marked in the log file as renamed or moved, the value of the corresponding attribute in the directory is renamed.
By default, when the Referential Integrity Postoperationplug-in is enabled, it performs integrity updates on the member, uniquemember, owner, and seeAlso attributes immediately after a delete or rename operation. However, the behavior of the Referential Integrity Postoperation plug-in can be configured to suit the needs of the directory in several different ways:
  • Record Referential Integrity updates in the replication change log.
  • Modify the update interval.
  • Select the attributes to which to apply Referential Integrity.
  • Disable Referential Integrity.
All attributes used in referential integrity must be indexed for presence and equality; not indexing those attributes results poor server performance for modify and delete operations.
nsIndexType: pres
nsIndexType: eq
nsIndexType: sub
See Section 13.2, “Creating Standard Indexes” for more information about checking and creating indexes.

5.2. Using Referential Integrity with Replication

There are certain limitations when using the Referential Integrity Postoperation plug-in in a replication environment:
  • Never enable it on a dedicated consumer server (a server that contains only read-only replicas).
  • Never enable it on a server that contains a combination of read-write and read-only replicas.
  • It is possible to enable it on a supplier server that contains only read-write replicas.
  • With multi-master replication, enable the plug-in on just one supplier.
If the replication environment satisfies the all of those condition, you can enable the Referential Integrity Postoperation plug-in.
  1. Enable the Referential Integrity Postoperation plug-in as described in Section 5.3, “Enabling and Disabling Referential Integrity”.
  2. Configure the plug-in to record any integrity updates in the changelog.
  3. Ensure that the Referential Integrity Postoperation plug-in is disabled on all consumer servers.

    Note

    Because the supplier server sends any changes made by the Referential Integrity Postoperation Integrity plug-in to consumer servers, it is unnecessary to run the Referential Integrity Postoperation plug-in on consumer servers.

5.3. Enabling and Disabling Referential Integrity

5.3.1. Enabling and Disabling Referential Integrity from the Command Line

To enable or disable the Referential Integrity Postoperation plug-in, set the nsslapd-pluginEnabled parameter in the plug-in's configuration entry:
For example, to enable the plug-in:
  1. Set the nsslapd-pluginEnabled parameter to on:
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn: cn=,cn=plugins,cn=config
    changetype: modify
    replace: nsslapd-pluginEnabled
    nsslapd-pluginEnabled: on
  2. Restart the instance:
    # systemctl restart dirsrv@instance_name

5.3.2. Enabling and Disabling Referential Integrity in the Console

To enable the Referential Integrity Postoperation plug-in, follow the procedure in Section 1.9.2.2, “Enabling Plug-ins in the Directory Server Console”.

5.4. Modifying the Update Interval

By default, the server performs Referential Integrity updates immediately after a delete or a modrdn operation. Depending on the amount of operations, this can cause a performance impact. To reduce the performance impact, you can increase the amount of time between updates.
Set the interval in seconds. Alternatively, you can set the following values:
  • 0: The check for referential integrity is performed immediately.
  • -1: No check for referential integrity is performed.

Important

If you set the update interval to 0, you can only enable the plug-in on all masters in a multi-master replication environment if you also set their Referential Integrity Postoperation plug-in's update interval to 0. However, if you configure a positive value on one master, you must not enable the plug-in on any other master to prevent replication loops and directory inconsistencies.
If you want to enable the plug-in in a multi-master replication environment, Red Hat recommends setting the update interval to 0 and to enable the plug-in on all masters.

5.4.1. Modifying the Update Interval Using the Command Line

To set the update interval using the command line to, for example, to update immediately:
  1. Set the interval in seconds in the referint-update-delay parameter:
    # ldapmodify -D "cn=Directory Manager" -W -x
    dn: cn=referential integrity postoperation,cn=plugins,cn=config
    changetype: modify
    replace: referint-update-delay
    referint-update-delay: 0
  2. Restart the Directory Server instance:
    # systemctl restart dirsrv@instance_name
Referential Integrity can only be enabled on one master. If you set the interval to 0, Directory Server cleans up references replicates these changes to all consumers immediately. If you set the interval to a value greater than 0, and the master who has Referential Integrity enabled is offline, the references are not cleaned up before this master is up again.

5.4.2. Modifying the Update Interval using the Console

To set the update interval using the Console:
  1. Open the Property Editor in the Referential Integrity Postoperation plug-in's configuration. For details, see Section 1.9.3.2, “Configuring Plug-ins using the Console”.
  2. Set the interval in seconds in the referint-update-delay parameter.

5.5. Modifying the Attribute List

By default, the Referential Integrity plug-in is set up to check for and update the member, uniquemember, owner, and seeAlso attributes. You can add or delete attributes to be updated using the command line or the Console.

Note

Attributes set in the Referential Integrity plug-in's parameter list, must have equality indexing on all databases. Otherwise, the plug-in scans every entry of the database for matching the deleted or modified DN. This can have a significant performance impact. For details about checking and creating indexes, see Section 13.2, “Creating Standard Indexes”.

5.5.1. Modifying the Attribute List Using the Console

  1. Open the Property Editor in the Referential Integrity Postoperation plug-in's configuration. For details, see Section 1.9.3.2, “Configuring Plug-ins using the Console”.
  2. Update the attributes in the referint-membership-attr attribute.
    You can add additional values or delete existing ones using the Add Value and Delete Value buttons.

5.5.2. Configuring the Attribute List from the Command Line

  1. Update the attribute list:
    • To add an additional attribute that should be checked and updated by the plug-in:
      # ldapmodify -D "cn=Directory Manager" -W -x
      
      dn: cn=referential integrity postoperation,cn=plugins,cn=config
      add: referint-membership-attr
      referint-membership-attr: attribute_name
    • To delete an attribute that should no longer be checked and updated by the plug-in:
      # ldapmodify -D "cn=Directory Manager" -W -x
      
      dn: cn=referential integrity postoperation,cn=plugins,cn=config
      delete: referint-membership-attr
      referint-membership-attr: attribute_name
  2. Restart the Directory Server instance:
    # systemctl restart dirsrv@instance_name

5.6. Configuring Scope for the Referential Integrity

If an entry is deleted, the references to it are deleted or modified to reflect the change. When this update is applied to all entries and all groups, it can impact performance and prevents flexibility of restricting the referential integrity to selected subtrees. Defining a scope addresses this problem.
For example, there may be one suffix, dc=example,dc=com, containing two subtrees: ou=active users,dc=example,dc=com and ou=deleted users,dc=example,dc=com. Entries in deleted users should not be handled for purposes of referential integrity.
The following three attributes can be used to define the scope in the Referential Integrity Postoperation plug-in configuration.
The nsslapd-pluginEntryScope attribute
This multi-value attribute controls the scope of the entry that is deleted or renamed. It defines the subtree in which the Referential Integrity Postoperation plug-in looks for the delete or rename operations of a user entry. If a user is deleted or renamed that does not exist under the defined subtree, the plug-in ignores the operation. The attribute allows you to specify to which branches of the database the plug-in should apply the operation.
nsslapd-pluginEntryScope: dn
The nsslapd-pluginExcludeEntryScope attribute
This attribute also controls the scope of the entry that is deleted or renamed. It defines the subtree in which the Referential Integrity Postoperation plug-in ignores any operations for deleting or renaming a user.
nsslapd-pluginExcludeEntryScope: dn
The nsslapd-pluginContainerScope attribute
This attribute controls the scope of groups in which references are updated. After a user is deleted, the Referential Integrity Postoperation plug-in looks for the groups to which the user belongs and updates them accordingly. This attribute specifies which branch the plug-in searches for the groups to which the user belongs. The Referential Integrity Postoperation plug-in only updates groups that are under the specified container branch, and leaves all other groups not updated.
nsslapd-pluginContainerScope: dn

Chapter 6. Populating Directory Databases

Databases contain the directory data managed by the Red Hat Directory Server.

6.1. Importing Data

Directory Server can populate a database with data in one of two ways: by importing data (either through the Directory Server Console or using the import tools) or by initializing a database for replication.
Table 6.1, “Import Method Comparison” describes the differences between an import and initializing databases.

Table 6.1. Import Method Comparison

Action Import Initialize Database
Overwrites database No Yes
LDAP operations Add, modify, delete Add only
Performance More time-consuming Fast
Partition specialty Works on all partitions Local partitions only
Response to server failure Best effort (all changes made up to the point of the failure remain) Atomic (all changes are lost after a failure)
LDIF file location Local to Console Local to Console or local to server
Imports configuration information (cn=config) Yes No

6.1.1. Setting EntryUSN Initial Values During Import

Entry update sequence numbers (USNs) are not preserved when entries are exported from one server and imported into another. As Section 4.1, “Tracking Modifications to the Database through Update Sequence Numbers” explains, entry USNs are assigned for operations that happen on a local server, so it does not make sense to import those USNs onto another server.
However, it is possible to configure an initial entry USN value for entries when importing a database or initializing a database (such as when a replica is initialized for replication). This is done by setting the nsslapd-entryusn-import-initval attribute, which sets a starting USN for all imported entries.
There are two possible values for nsslapd-entryusn-import-initval:
  • An integer, which is the explicit start number used for every imported entry.
  • next, which means that every imported entry uses whatever the highest entry USN value was on the server before the import operation, incremented by one.
If nsslapd-entryusn-import-initval is not set, then all entry USNs begin at zero.
For example, if the highest value on the server is 1000 before the import or initialization operation, and the nsslapd-entryusn-import-initval value is next, then every imported entry is assigned a USN of 1001:
# ldapsearch -D "cn=Directory Manager" -W -p 389 -h server.example.com -x "(cn=*)" entryusn

dn: dc=example,dc=com
entryusn: 1001
dn: ou=Accounting,dc=example,dc=com
entryusn: 1001
dn: ou=Product Development,dc=example,dc=com
entryusn: 1001
...
dn: uid=jsmith,ou=people,dc=example,dc=com
entryusn: 1001
...
To set an initial value for entry USNs, simply add the nsslapd-entryusn-import-initval attribute to the server into which data are being imported or to the master server which will perform the initialization.
# ldapmodify -D "cn=Directory Manager" -W -x -D "cn=directory manager" -W -p 389 -h server.example.com -x

dn: cn=config
changetype: modify
add: nsslapd-entryusn-import-initval
nsslapd-entryusn-import-initval: next

Note

In multi-master replication, the nsslapd-entryusn-import-initval attribute is not replicated between servers. This means that the value must be set specifically on whichever supplier server is being used to initialize a replica.
For example, if Supplier1 has nsslapd-entryusn-import-initval set to next and is used to initialize a replica, then the entry USNs for imported entries have the highest value plus one. If Supplier2 does not have nsslapd-entryusn-import-initval set and is used to initialize a replica, then all entry USNs for imported entries begin at zero — even if Supplier1 and Supplier 2 have a multi-master replication agreement between them.

6.1.2. Importing a Database from the Console

When performing an import operation from the Directory Server Console, an ldapmodify operation is executed to append data, as well as to modify and delete entries. The operation is performed on all of the databases managed by the Directory Server and on remote databases to which the Directory Server has a configured database link.
Import operations can be run on a server instance that is local to the Directory Server Console or on a different host machine (a remote import operation).
You must be logged in as the Directory Manager in order to perform an import.

Note

The LDIF files used for import operations must use UTF-8 character set encoding. Import operations do not convert data from local character set encoding to UTF-8 characterset encoding.

Warning

All imported LDIF files must also contain the root suffix.
To import data from the Directory Server Console:
  1. Select the Tasks tab. Scroll to the bottom of the screen, and select Import Database.
    Alternatively, open the Configuration tab and select Import from the Console menu.
  2. In the Import Database dialog box, enter the full path to the LDIF file to import in the LDIF file field, or click Browse to select the file to import.
    If the Console is running on a machine remote to the directory, the field name appears as LDIF file (on the machine running the Console). When browsing for a file, you are not browsing the current directory for the Directory Server host, but the filesystem of the machine running the Console.
    When importing a database through a remote Console, do not use a relative path to the database. For remote imports, the operation fails with the error Cannot write to file... if a relative path is given for the file. Always use an absolute path for remote import operations.
  3. In the Options box, select one or both of the following options:
    • Add Only. The LDIF file may contain modify and delete instructions in addition to the default add instructions. For the server to ignore operations other than add, select the Add only check box.
    • Continue on Error. Select the Continue on error check box for the server to continue with the import even if errors occur. For example, use this option to import an LDIF file that contains some entries that already exist in the database in addition to new ones. The server notes existing entries in the rejects file while adding all new entries.
  4. In the File for Rejects field, enter the full path to the file in which the server is to record all entries it cannot import, or click Browse to select the file which will contain the rejects.
    A reject is an entry which cannot be imported into the database; for example, the server cannot import an entry that already exists in the database or an entry that has no parent object. The Console will write the error message sent by the server to the rejects file.
    Leaving this field blank means the server will not record rejected entries.
The server performs the import and also creates indexes.

Note

Trailing spaces are dropped during a remote Console import but are preserved during both local Console or ldif2db import operations.

6.1.3. Initializing a Database from the Console

The existing data in a database can be overwritten by initializing databases.
You must be logged in as the Directory Manager in order to initialize a database because an LDIF file that contains a root entry cannot be imported into a database except as the Directory Manager (root DN). Only the Directory Manager has access to the root entry, such as dc=example,dc=com.

Warning

When initializing databases from an LDIF file, be careful not to overwrite the o=NetscapeRoot suffix unless you are restoring data. Otherwise, initializing the database deletes information and may require re-installing the Directory Server.
To initialize a database using the Directory Server Console:
  1. Select the Configuration tab.
  2. Expand the Data tree in the left navigation pane. Expand the suffix of the database to initialize, then click the database itself.
  3. Right-click the database, and select Initialize Database.
    Alternatively, select Initialize Database from the Object menu.
  4. In the LDIF file field, enter the full path to the LDIF file to import, or click Browse.
  5. If the Console is running from a machine local to the file being imported, click OK and proceed with the import immediately. If the Console is running from a machine remote to the server containing the LDIF file, select one of the following options, then click OK:
    • From local machine. Indicates that the LDIF file is located on the local machine.
    • From server machine. Indicates that the LDIF file is located on a remote server.
    The default LDIF directory is /var/lib/dirsrv/slapd-instance/ldif.

6.1.4. Importing from the Command Line

There are four methods for importing data through the command line:

Note

The LDIF files used for import operations must use UTF-8 character set encoding. Import operations do not convert data from local character set encoding to UTF-8 characterset encoding.

Warning

All imported LDIF files must also contain the root suffix.

Note

To import a database that has been encrypted, use the -E option with the script. See Section 10.7, “Exporting and Importing an Encrypted Database” for more information.

6.1.4.1. Importing Using the ldif2db Command-Line Script

The ldif2db script overwrites the data in the specified database. Also, the script requires that the Directory Server be stopped when the import begins.
By default, the script first saves and then merges any existing o=NetscapeRoot configuration information with the o=NetscapeRoot configuration information in the files being imported.

Warning

This script overwrites the data in the database.
To import an LDIF:
  1. Stop the server:
    # systemctl stop dirsrv@instance
  2. Run the ldif2db command-line script:
    # ldif2db -Z instance_name -n Database1 -i /var/lib/dirsrv/slapd-instance/ldif/demo.ldif -i /var/lib/dirsrv/slapd-instance/ldif/demo2.ldif
    For information about the parameters used in the example, see the description of the ldif2db script in the Red Hat Directory Server Configuration, Command, and File Reference.

    Warning

    If the database specified in the -n option does not correspond with the suffix contained by the LDIF file, all of the data contained by the database is deleted, and the import fails. Make sure that the database name is not misspelled.
  3. Start the server:
    # systemctl start dirsrv@instance

6.1.4.2. Importing Using the ldif2db.pl Perl Script

As with the ldif2db script, the ldif2db.pl script overwrites the data in the specified database. This script requires the server to be running in order to perform the import.

Warning

This script overwrites the data in the database.
Run the ldif2db.pl script:
# ldif2db.pl -Z instance_name -D "cn=Directory Manager" -w secret -i /var/lib/dirsrv/slapd-instance/ldif/demo.ldif -n Database1
For information about the parameters used in the example, see the description of the ldif2db.pl script in the Red Hat Directory Server Configuration, Command, and File Reference.

Note

You do not need root privileges to run the script, but you must authenticate as the Directory Manager.

6.1.4.3. Importing Using the ldif2ldap Command-Line Script

The ldif2ldap script appends the LDIF file through LDAP. Using this script, data are imported to all directory databases at the same time. The server must be running in order to import using ldif2ldap.
To import LDIF using ldif2ldap:
[root@server ~]# ldif2ldap -Z instance_name -D "cn=Directory Manager" -w secretpwd /var/lib/dirsrv/slapd-instance/ldif/demo.ldif
The ldif2ldap script requires the DN of the administrative user, the password of the administrative user, and the absolute path and filename of the LDIF files to be imported.
For information about the parameters used in the example, see the description of the ldif2ldap script in the Red Hat Directory Server Configuration, Command, and File Reference.

6.1.4.4. Importing through the cn=tasks Entry

The cn=tasks,cn=config entry in the Directory Server configuration is a container entry for temporary entries that the server uses to manage tasks. Several common directory tasks have container entries under cn=tasks,cn=config. Temporary task entries can be created under cn=import,cn=tasks,cn=config to initiate an import operation.
As with the ldif2db and ldif2db.pl scripts, an import operation in cn=tasks overwrites all of the information in the database.
This task entry requires three attributes:
  • A unique name (cn)
  • The filename of the LDIF file to import (nsFilename)
  • The name of the database into which to import the file (nsInstance)
It is also possible to supply the DNs of suffixes to include or exclude from the import, analogous to the -s and -x options, respectively, for the ldif2db and ldif2db.pl scripts.
The entry is simply added using ldapmodify, as described in Section 3.1.3.2, “Adding an Entry Using ldapmodify. For example:
# ldapmodify -a -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: cn=example import,cn=import,cn=tasks,cn=config
changetype: add
objectclass: extensibleObject
cn: example import
nsFilename: /home/files/example.ldif
nsInstance: userRoot
nsIncludeSuffix: ou=People,dc=example,dc=com
nsExcludeSuffix: ou=Groups,dc=example,dc=com
As soon as the task is completed, the entry is removed from the directory configuration.
For details about the attributes used in the example and other attributes you can set in this entry, see the cn=import,cn=tasks,cn=config entry description in the Red Hat Directory Server Configuration, Command, and File Reference

6.2. Exporting Data

LDAP Data Interchange Format (LDIF) files are used to export database entries from the Directory Server databases. LDIF is a standard format described in RFC 2849, The LDAP Data Interchange Format (LDIF) - Technical Specification.
Exporting data can be useful for the following:
  • Backing up the data in the database.
  • Copying data to another Directory Server.
  • Exporting data to another application.
  • Repopulating databases after a change to the directory topology.
For example, if a directory contains one database, and its contents are split into two databases, then the two new databases receive their data by exporting the contents of the old databases and importing it into the two new databases, as illustrated in Figure 6.1, “Splitting a Database Contents into Two Databases”.

Note

The export operations do not export the configuration information (cn=config), schema information (cn=schema), or monitoring information (cn=monitor).
Splitting a Database Contents into Two Databases

Figure 6.1. Splitting a Database Contents into Two Databases

The Directory Server Console or command-line utilities can be used to export data.

Warning

Do not stop the server during an export operation.

6.2.1. Exporting Directory Data to LDIF Using the Console

Some or all of directory data can be exported to LDIF, depending upon the location of the final exported file. When the LDIF file is on the server, only the data contained by the databases local to the server can be exported. If the LDIF file is remote to the server, all of the databases and database links can be exported.
Export operations can be run to get data from a server instance that is local to the Directory Server Console or from a different host machine (a remote export operation).
Export directory data to LDIF from the Directory Server Console while the server is running:
  1. Select the Tasks tab. Scroll to the bottom of the screen, and click Export Database(s).
    Alternatively, select the Configuration tab and click the Export from the Console menu.
  2. Enter the full path and filename of the LDIF file in the LDIF File field, or click Browse to locate the file.
    Browse is not enabled if the Console is running on a remote server. When the Browse button is not enabled, the file is stored in the default directory, /var/lib/dirsrv/slapd-instance/ldif.
  3. If the Console is running on a machine remote to the server, two radio buttons are displayed beneath the LDIF File field.
    • Select To local machine to export the data to an LDIF file on the machine from which the Console is running.
    • Select To server machine to export to an LDIF file located on the server's machine.
  4. To export the whole directory, select the Entire database radio button.
    To export only a single subtree of the suffix contained by the database, select the Subtree radio button, and then enter the name of the suffix in the Subtree text box. This option exports a subtree that is contained by more than one database.
    Alternatively, click Browse to select a suffix or subtree.

6.2.2. Exporting a Single Database to LDIF Using the Console

It is also possible to export a single database to LDIF. Do the following while the server is running:
  1. Select the Configuration tab.
  2. Expand the Data tree in the left navigation pane. Expand the suffix, and select the database under the suffix.
  3. Right-click the database, and select Export Database.
    Alternatively, select Export Database from the Object menu.
  4. In the LDIF file field, enter the full path to the LDIF file, or click Browse.
    When the Browse button is not enabled, the file is stored in the default directory, /var/lib/dirsrv/slapd-instance/ldif.

6.2.3. Exporting a Database to LDIF Using the Command Line

Directory Server supports the following ways to export data into LDIF files:

6.2.3.1. Exporting a Database While Directory Server is Running

To export a database while Directory Server is running, create an export task. You can either use the db2ldif.pl script to create it or create the task manually. After the task is completed, Directory Server automatically removes the task entry from the cn=export,cn=tasks,cn=config entry.
For a comparison of which db2ldif.pl command-line option sets which attribute in the task entry, see the Red Hat Directory Server Configuration, Command, and File Reference.
6.2.3.1.1. Exporting a Database Using the db2ldif.pl Script
The db2ldif.pl script creates a task to export a database while Directory Server is running. For example, to export the userRoot database:
# db2ldif.pl -Z instance_name -D "cn=Directory Manager" -w - -n userRoot
By default, the script stores the exported data in the /var/lib/dirsrv/slapd-instance_name/ldif/ directory. The created file is named instance_name-database_or_suffix_name-time_stamp.ldif. Alternatively, you can pass the -a file_name option to the script to set a different location. Note that the Directory Server user requires write permissions in the destination directory.
For details about the available command-line options, see the description of the script in the Red Hat Directory Server Configuration, Command, and File Reference.
6.2.3.1.2. Manually Creating an Export Task
Instead of using the db2ldif.pl script to create an export task, you can create the task entry manually. For example, to create a task that exports the userRoot database to the /tmp/export.ldif file:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: cn=task_name,cn=export,cn=tasks,cn=config
objectclass: extensibleObject
cn: task_name
nsInstance: userRoot
nsFilename: /tmp/export.ldif
For a list of settings which you can use in export task entries, see the Red Hat Directory Server Configuration, Command, and File Reference.

6.2.3.2. Exporting a Database While Directory Server is Stopped

To export a database while the Directory Server instance is stopped, use the db2ldif script. The script takes the same options as the db2ldif.pl script, which can export data while the instance is running.
For example, to export the userRoot database while the instance is stopped:
# db2ldif -Z instance_name -D "cn=Directory Manager" -w - -n userRoot
By default, the script stores the exported data in the /var/lib/dirsrv/slapd-instance_name/ldif/ directory. The created file is named instance_name-database_or_suffix_name-time_stamp.ldif. Alternatively, you can pass the -a file_name option to the script to set a different location. Note that the Directory Server user requires write permissions in the destination directory.
For details about the available command-line options, see the description of the script in the Red Hat Directory Server Configuration, Command, and File Reference.

6.3. Backing up and Restoring Data

Databases can be backed up and restored using the Directory Server Console or a command-line script. A backup contains, for example:
  • All database files, such as for userRoot and NetscapeRoot, including the data stored within these databases
  • The transaction logs
  • The Indices
In contrast to a backup, you can export data as described in Section 6.2, “Exporting Data”. Use the export feature to export specific data, such as a subtree, from a server in the LDAP Data Interchange Format (LDIF) format.
This section describes the following procedures:

Warning

Do not stop the server during a backup or restore operation.

6.3.1. Backing up All Databases

The following procedures describe backing up all of the databases in the directory using the Directory Server Console and from the command line.

Note

These backup methods cannot be used to back up the data contained by databases on a remote server that are chained using database links.

6.3.1.1. Backing up All Databases from the Console

When backing up databases from the Directory Server Console, the server copies all of the database contents and associated index files to a backup location. A backup can be performed while the server is running.
To back up databases from the Directory Server Console:
  1. Select the Tasks tab.
  2. Click Back Up Directory Server.
  3. Enter the full path of the directory to store the backup file in the Directory text box, or click Use default, and the server provides a name for the backup directory.
    If the Console is running on the same machine as the directory, click Browse to select a local directory.
    With the default location, the backup files are placed in /var/lib/dirsrv/slapd-instance/bak. By default, the backup directory name contains the name of the server instance and the time and date the backup was created (instance-YYYY_MM_DD_hhmmss).

6.3.1.2. Backing up All Databases from the Command Line

Databases can be backed up from the command line using either the db2bak command-line script or the db2bak.pl Perl script. The command-line script works when the server is running or when the server is stopped; the Perl script can only be used when the server is running.

Important

If the database being backed up is a master database, meaning it keeps a changelog, then it must be backed up using the db2bak.pl Perl script or using the Directory Server Console if the server is kept running. The changelog only writes its RUV entries to the database when the server is shut down; while the server is running, the changelog keeps its changes in memory. For the Perl script and the Console, these changelog RUVs are written to the database before the backup process runs. However, that step is not performed by the command-line script.
The db2bak should not be run on a running master server. Either use the Perl script or stop the server before performing the backup.
Configuration information cannot be backed up using this backup method. For information on backing up the configuration information, see Section 6.3.2, “Backing up the dse.ldif Configuration File”.
To back up the directory from the command line using the db2bak.pl script, run the db2bak.pl Perl script, specifying the backup filename and directory.
# db2bak.pl -Z instance_name -D "cn=Directory Manager" -w password -a /var/lib/dirsrv/slapd-example/bak/instance-2018_04_30_16_27_5-custom-name

Note

Do not use a trailing slash character ("/") when using the -a option to specify the default backup directory that is configured using the nsslapd-bakdir directive. For example:
# db2bak.pl -Z instance_name -D "cn=Directory Manager" -w password -a /var/lib/dirsrv/slapd-example/bak
Note the lack of slash after slapd-example/bak.
This limitation only applies when specifying exactly the same directory which is configured in nsslapd-bakdir. Any other directory, even inside the default backup directory (for example, bak/custom-name/) can be specified with or without a trailing slash.
The backup directory where the server saves the backed up databases can be specified with the script. If a directory is not specified, the backup file is stored in /var/lib/dirsrv/slapd-instance/bak. By default, the backup directory is named with the Directory Server instance name and the date of the backup (serverID-YYYY_MM_DD_hhmmss).
For information about ldif2db, see the script's description in the Red Hat Directory Server Configuration, Command, and File Reference.

6.3.1.3. Backing up the Database through the cn=tasks Entry

The cn=tasks,cn=config entry in the Directory Server configuration is a container entry for temporary entries that the server uses to manage tasks. Several common directory tasks have container entries under cn=tasks,cn=config. Temporary task entries can be created under cn=backup,cn=tasks,cn=config to initiate a backup operation.
The backup task entry requires three attributes:
  • A unique name (cn).
  • The directory to write the backup file to (nsArchiveDir). The backup file is named with the Directory Server instance name and the date of the backup (serverID-YYYY_MM_DD_hhmmss).
  • The type of database (nsDatabaseType); the only option is ldbm database.
The entry is simply added using ldapmodify, as described in Section 3.1.3.2, “Adding an Entry Using ldapmodify. For example:
# ldapmodify -a -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: cn=example backup,cn=backup,cn=tasks,cn=config
changetype: add
objectclass: extensibleObject
cn: example backup
nsArchiveDir: /export/backups/
nsDatabaseType: ldbm database
As soon as the task is completed, the entry is removed from the directory configuration.
For details about the attributes used in the example and other attributes you can set in this entry, see the cn=backup,cn=tasks,cn=config entry description in the Red Hat Directory Server Configuration, Command, and File Reference

6.3.2. Backing up the dse.ldif Configuration File

Directory Server automatically backs up the dse.ldif configuration file. When the Directory Server is started, the directory creates a backup of the dse.ldif file automatically in a file named dse.ldif.startOK in the /etc/dirsrv/slapd-instance directory.
When the dse.ldif file is modified, the file is first backed up to a file called dse.ldif.bak in the /etc/dirsrv/slapd-instance directory before the directory writes the modifications to the dse.ldif file.

6.3.3. Restoring All Databases

The following procedures describe restoring all of the databases in the directory using the Directory Server Console and from the command line.

Note

Restoring a database from backup also restores the changelog.

Important

While restoring databases, the server must be running. However, the databases will be unavailable for processing operations during the restore.
Therefore, stop all replication processes before restoring a database. For details, see Section 15.8.1, “Disabling Replication”.

6.3.3.1. Restoring All Databases from the Console

If the databases become corrupted, restore data from a previously generated backup using the Directory Server Console. This process consists of stopping the server and then copying the databases and associated index files from the backup location to the database directory.

Warning

Restoring databases overwrites any existing database files.

Important

While restoring databases, the server must be running. However, the databases will be unavailable for processing operations during the restore.
Therefore, stop all replication processes before restoring a database. For details, see Section 15.8.1, “Disabling Replication”.
To restore databases from a previously created backup:
  1. In the Directory Server Console, select the Tasks tab.
  2. Click Restore Directory Server.
  3. Select the backup from the Available Backups list, or enter the full path to a valid backup in the Directory text box.
    The Available Backups list shows all backups located in the default directory, /var/lib/dirsrv/slapd-instance/bak/backup_directory. backup_directory is the directory of the most recent backup, in the form serverID-YYYY_MM_DD_hhmmss.

6.3.3.2. Restoring Databases from the Command Line

There are three ways to restore databases from the command line:
  • Using the bak2db command-line script. This script requires the server to be shut down.
  • Using the bak2db.pl Perl script. This script works while the server is running.
  • Creating a temporary entry under cn=restore,cn=tasks,cn=config. This method can also be run while the server is running.

Important

While restoring databases, the server must be running (with the exception of running the bak2db command-line script). However, the databases will be unavailable for processing operations during the restore.
Therefore, stop all replication processes before restoring a database. For details, see Section 15.8.1, “Disabling Replication”.
6.3.3.2.1. Using the bak2db Command-Line Script
  1. If the Directory Server is running, stop it:
    # systemctl stop dirsrv@instance
  2. Run the bak2db command-line script. The bak2db script requires the full path and name of the input file.
    # bak2db -Z instance_name /var/lib/dirsrv/slapd-instance/bak/instance-2018_04_30_11_48_30
    For information about the parameters used in the example, see the description of the bak2db script in the Red Hat Directory Server Configuration, Command, and File Reference.
6.3.3.2.2. Using bak2db.pl Perl Script
Run the bak2db.pl Perl script.
# bak2db.pl -Z instance_name -D "cn=Directory Manager" -w secret -a /var/lib/dirsrv/slapd-instance/bak/instance-2018_04_30_11_48_30
For information about the parameters used in the example, see the description of the bak2db.pl script in the Red Hat Directory Server Configuration, Command, and File Reference.

Important

While restoring databases, the server must be running. However, the databases will be unavailable for processing operations during the restore.
Therefore, stop all replication processes before restoring a database. For details, see Section 15.8.1, “Disabling Replication”.
6.3.3.2.3. Restoring the Database through the cn=tasks Entry
The cn=tasks,cn=config entry in the Directory Server configuration is a container entry for temporary entries that the server uses to manage tasks. Several common directory tasks have container entries under cn=tasks,cn=config. Temporary task entries can be created under cn=restore,cn=tasks,cn=config to initiate a restore operation.

Important

While restoring databases, the server must be running. However, the databases will be unavailable for processing operations during the restore.
Therefore, stop all replication processes before restoring a database. For details, see Section 15.8.1, “Disabling Replication”.
The restore task entry requires three attributes, the same as the backup task:
  • A unique name (cn).
  • The directory from which to retrieve the backup file (nsArchiveDir).
  • The type of database (nsDatabaseType); the only option is ldbm database.
The entry is simply added using ldapmodify, as described in Section 3.1.3.2, “Adding an Entry Using ldapmodify. For example:
# ldapmodify -a -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: cn=example restore,cn=restore,cn=tasks,cn=config
changetype: add
objectclass: extensibleObject
cn: example restore
nsArchiveDir: /export/backups/
nsDatabaseType: ldbm database
As soon as the task is completed, the entry is removed from the directory configuration.
For details about the attributes used in the example and other attributes you can set in this entry, see the cn=restore,cn=tasks,cn=config entry description in the Red Hat Directory Server Configuration, Command, and File Reference

6.3.4. Restoring a Single Database

It is possible to restore a single database through the command line, but not in the Directory Server Console. To restore a single database:
  1. Stop the Directory Server if it is running.
    # systemctl stop dirsrv@instance
  2. Restore the back end from the /var/lib/dirsrv/slapd-instance/bak archives with the bak2db script, using the -n parameter to specify the database name. For example:
    # bak2db -Z instance_name /var/lib/dirsrv/slapd-instance/bak/backup_file -n userRoot
  3. Restart the Directory Server.
    # systemctl start dirsrv@instance

    Note

    If the Directory Server fails to start, remove the database transaction log files in /var/lib/dirsrv/slapd-instance/db/log.###, then retry starting the server.

6.3.5. Restoring Databases That Include Replicated Entries

Several situations can occur when a supplier server is restored:
  • The consumer servers are also restored.
    For the very unlikely situation, that all databases are restored from backups taken at exactly the same time (so that the data are in sync), the consumers remain synchronized with the supplier, and it is not necessary to do anything else. Replication resumes without interruption.
  • Only the supplier is restored.
    If only the supplier is restored or if the consumers are restored from backups taken at a different times, reinitialize the consumers for the supplier to update the data in the database. If only the supplier is restored or if the consumers are restored from backups taken at a different times, reinitialize the consumers for the supplier to update the data in the database.
  • Changelog entries have not yet expired on the supplier server.
    If the supplier's changelog has not expired since the database backup was taken, then restore the local consumer and continue with normal operations. This situation occurs only if the backup was taken within a period of time that is shorter than the value set for the maximum changelog age attribute, nsslapd-changelogmaxage, in the cn=changelog5,cn=config entry. For more information about this option, see the Red Hat Directory Server Configuration, Command, and File Reference.
    Directory Server automatically detects the compatibility between the replica and its changelog. If a mismatch is detected, the server removes the old changelog file and creates a new, empty one.
  • Changelog entries have expired on the supplier server since the time of the local backup.
    If changelog entries have expired, reinitialize the consumer. For more information on reinitializing consumers, see Section 15.16, “Initializing Consumers”.

Example 6.1. Restoring a Directory Server Replication Topology

For example, to restore all servers in a replication environment, consisting of two masters and two consumer server:
  1. Restore the first master. Use the ldif2db utility without the -r option to import the data. See Section 6.1.4, “Importing from the Command Line”.
  2. Online-initialize the remaining servers by using replication:
    1. Initialize the second master from the first one.
    2. Initialize the consumers from the master.
  3. On each server, display the nsds5replicaLastUpdateStatus attribute to verify that replication works correctly:
    # ldapsearch -D "cn=Directory Manager" -W -p 389 -h server.example.com -b "cn=example_agreement,cn=replica,cn=dc\=example\,dc\=com,cn=mapping tree,cn=config" nsds5replicaLastUpdateStatus
    For details about possible statuses, see the Replication Agreement Status appendix in the Red Hat Directory Server Configuration, Command, and File Reference.
The changelog associated with the restored database will be erased during the restore operation. A message will be logged to the supplier servers' log files indicating that reinitialization is required.
For information on managing replication, see Chapter 15, Managing Replication.

6.3.6. Restoring the dse.ldif Configuration File

The directory creates two backup copies of the dse.ldif file in the /etc/dirsrv/slapd-instance directory. The dse.ldif.startOK file records a copy of the dse.ldif file at server start up. The dse.ldif.bak file contains a backup of the most recent changes to the dse.ldif file. Use the version with the most recent changes to restore the directory.
To restore the dse.ldif configuration file:
  1. Stop the server.
    # systemctl stop dirsrv@instance
  2. Restore the database as outlined in Section 6.3.4, “Restoring a Single Database” to copy the backup copy of the dse.ldif file into the directory.
  3. Restart the server.
    # systemctl restart dirsrv@instance

Chapter 7. Managing Attributes and Values

Red Hat Directory Server provides several different mechanisms for dynamically and automatically maintaining some types of attributes on directory entries. These plug-ins and configuration options simplify managing directory data and expressing relationships between entries.
Part of the characteristic of entries are their relationships to each other. Obviously, a manager has an employee, so those two entries are related. Groups are associated with their members. There are less apparent relationships, too, like between entries which share a common physical location.
Red Hat Directory Server provides several different ways that these relationships between entries can be maintained smoothly and consistently. There are several plug-ins can apply or generate attributes automatically as part of the data within the directory, including classes of service, linking attributes, and generating unique numeric attribute values.

7.1. Enforcing Attribute Uniqueness

To ensure that the value of an attribute is unique across the directory or subtree, use the Attribute Uniqueness plug-in.
If you want multiple attributes to be unique or if you want to use different conditions, create multiple configuration records of the plug-in.

7.1.1. Creating a New Configuration Record of the Attribute Uniqueness Plug-in

For each attribute whose values must be unique, create a new configuration record of the Attribute Uniqueness plug-in.

Note

You can only create a new configuration record of the plug-in from the command line.
To create a new unconfigured and disabled configuration record of the plug-in named Example Attribute Uniqueness:
# ldapadd -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
dn: cn=Example Attribute Uniqueness,cn=plugins,cn=config
objectClass: top
objectClass: nsSlapdPlugin
objectClass: extensibleObject
cn: Example Attribute Uniqueness
nsslapd-pluginPath: libattr-unique-plugin
nsslapd-pluginInitfunc: NSUniqueAttr_Init
nsslapd-pluginType: betxnpreoperation
nsslapd-pluginEnabled: off
nsslapd-plugin-depends-on-type: database
nsslapd-pluginId: NSUniqueAttr
nsslapd-pluginVersion: none
nsslapd-pluginVendor: 389 Project
nsslapd-pluginDescription: Enforce unique attribute values
uniqueness-attribute-name: uid

7.1.2. Configuring Attribute Uniqueness over Suffixes or Subtrees

You can configure the Attribute Uniqueness plug-in to ensure that values of an attribute are unique in certain suffixes, subtrees, or over suffixes and subtrees.

7.1.2.1. Configuring Attribute Uniqueness over Suffixes or Subtrees Using the Command Line

To configure, for example, that values stored in mail attributes are unique:
  1. Create a new configuration record of the Attribute Uniqueness plug-in named, for example, mail Attribute Uniqueness. For details, see Section 7.1.1, “Creating a New Configuration Record of the Attribute Uniqueness Plug-in”.
  2. Enable the plug-in configuration record and configure that values stored in mail attributes must be unique inside, for example, the ou=Engineering,dc=example,dc=com and ou=Sales,dc=example,dc=com subtrees:
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn: cn=mail Attribute Uniqueness,cn=plugins,cn=config
    changetype: modify
    replace: nsslapd-pluginEnabled
    nsslapd-pluginEnabled: on
    -
    add: uniqueness-attribute-name
    uniqueness-attribute-name: mail
    -
    add: uniqueness-subtrees
    uniqueness-subtrees: ou=Engineering,dc=example,dc=com
    uniqueness-subtrees: ou=Sales,dc=example,dc=com
  3. Optionally, to configure uniqueness across all subtrees configured in this plug-in configuration record:
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn: cn=mail Attribute Uniqueness,cn=plugins,cn=config
    changetype: modify
    add: uniqueness-across-all-subtrees
    uniqueness-across-all-subtrees: on
  4. Restart the instance:
    # systemctl restart dirsrv@instance_name

7.1.2.2. Configuring Attribute Uniqueness over Suffixes or Subtrees Using the Console

To configure, for example, that values stored in mail attributes are unique:
  1. Create a new configuration record of the Attribute Uniqueness plug-in. See Section 7.1.1, “Creating a New Configuration Record of the Attribute Uniqueness Plug-in”.
  2. Open the Property Editor in the plug-in configuration record's configuration. For details, see Section 1.9.3.2, “Configuring Plug-ins using the Console”.
  3. To enable the plug-in, set:
    nsslapd-pluginEnabled: on
  4. Set that the mail attribute must be unique:
    uniqueness-attribute-name: mail
  5. Set the subtrees in which the attribute's value must be unique:
    uniqueness-subtrees: ou=Engineering,dc=example,dc=com
    uniqueness-subtrees: ou=Sales,dc=example,dc=com
    Select the value field of the uniqueness-subtrees attribute and click the Add Value button to add the second uniqueness-subtrees attribute.
  6. Optionally, to configure uniqueness across all subtrees configured in this plug-in configuration record, add the uniqueness-across-all-subtrees attribute and set it to on:
    uniqueness-across-all-subtrees: on
  7. Click OK to close the Property Editor

7.1.3. Configuring Attribute Uniqueness over Object Classes

You can configure the Attribute Uniqueness plug-in to ensure that values of an attribute are unique in subtree entries that contain a specific object class. Directory Server searches for this object class in the parent entry of the updated object. If Directory Server did not find the object class, the search continues at the next higher level entry up to the root of the directory tree. If the object class was found, Directory Server verifies that the value of the attribute set in uniqueness-attribute-name is unique in this subtree.

Note

You can configure this scenario only using the command line.
To configure, for example, that values stored in mail attributes are unique under the entry that contains the nsContainer object class:
  1. Create a new configuration record of the Attribute Uniqueness plug-in named, for example, mail Attribute Uniqueness. For details, see Section 7.1.1, “Creating a New Configuration Record of the Attribute Uniqueness Plug-in”.
  2. Enable the plug-in configuration record and configure that values stored in mail attributes must be unique under the entry that contains the nsContainer object class:
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn: cn=mail Attribute Uniqueness,cn=plugins,cn=config
    changetype: modify
    replace: nsslapd-pluginEnabled
    nsslapd-pluginEnabled: on
    -
    add: uniqueness-top-entry-oc
    uniqueness-top-entry-oc: nsContainer
  3. Optionally, you can limit the scope of objects being checked. If you want the server to check only a subset of entries under the entry that contains the nsContainer object class, set an additional object class in the uniqueness-subtree-entries-oc parameter. This additional class will also have to be present.
    For example, the mail attribute must be unique in all entries under the entry that contains the nsContainer object class set. However, you want that the plug-in only searches the mail in entries that contain a object class that provides this attribute, such as inetOrgPerson. In this situation enter:
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn: cn=mail Attribute Uniqueness,cn=plugins,cn=config
    add: uniqueness-subtree-entries-oc
    uniqueness-subtree-entries-oc: inetOrgPerson
  4. Restart the instance:
    # systemctl restart dirsrv@instance_name

7.1.4. Attribute Uniqueness Plug-in Configuration Parameters

To configure an Attribute Uniqueness plug-in configuration record, set the plug-in's configuration attributes in the cn=attribute_uniqueness_configuration_record_name,cn=plugins,cn=config entry.
You can configure this plug-in using the new plug-in-specific attribute names (Example 7.1, “Attribute Uniqueness Plug-in Configuration Using Plug-in-specific Attributes”) or using the deprecated nsslapd-plugarg* attributes (Example 7.2, “Attribute Uniqueness Plug-in Configuration Using nsslapd-pluginarg* Attributes”).

Important

Red Hat recommends using only the plug-in-specific attribute names to configure the Attribute Uniqueness plug-in.

Example 7.1. Attribute Uniqueness Plug-in Configuration Using Plug-in-specific Attributes

dn: cn=Example Attribute Uniqueness,cn=plugins,cn=config
nsslapd-pluginEnabled: on
uniqueness-attribute-name: attribute_name
uniqueness-top-entry-oc: objectclass1 
uniqueness-subtree-entries-oc: objectclass2

Example 7.2. Attribute Uniqueness Plug-in Configuration Using nsslapd-pluginarg* Attributes

dn: cn=Example Attribute Uniqueness,cn=plugins,cn=config
nsslapd-pluginEnabled: on
nsslapd-pluginarg0: attribute=mail
nsslapd-pluginarg1: markerObjectClass=objectclass1 
nsslapd-pluginarg2: requiredObjectClass=objectclass2

Table 7.1. Attribute Uniqueness Plug-in Configuration Parameters

Parameter New or Old Syntax Definition
cn Both Sets the name of the Attribute Uniqueness plug-in configuration record. You can use any string, but Red Hat recommends naming the configuration record attribute_name Attribute Uniqueness.
nsslapd-pluginEnabled Both Enables (on) or disables (off) the plug-in configuration record.
uniqueness-attribute-name New Sets the name of the attribute whose values must be unique. This attribute is multi-valued.
uniqueness-subtrees New Sets the DN under which the plug-in checks for uniqueness of the attribute's value. This attribute is multi-valued.
uniqueness-across-all-subtrees New If enabled (on), the plug-in checks that the attribute is unique across all subtrees set. If you set the attribute to off, uniqueness is only enforced within the subtree of the updated entry.
uniqueness-top-entry-oc New Directory Server searches this object class in the parent entry of the updated object. If it was not found, the search continues at the next higher level entry up to the root of the directory tree. If the object class was found, Directory Server verifies that the value of the attribute set in uniqueness-attribute-name is unique in this subtree.
uniqueness-subtree-entries-oc New Optionally, when using the uniqueness-top-entry-oc parameter, you can configure that the Attribute Uniqueness plug-in only verifies if an attribute is unique, if the entry contains the object class set in this parameter. For details, see Section 7.1.3, “Configuring Attribute Uniqueness over Object Classes”.
nsslapd-pluginarg0 Old
The plug-in-specific attribute equivalent of this nsslapd-pluginarg* parameter is uniqueness-attribute-name. See this parameter for a description.
Set the attribute to attribute=attribute_name.
nsslapd-pluginarg[1-9] Old
The plug-in-specific attribute equivalent of this nsslapd-pluginarg* parameter is uniqueness-top-entry-oc. See this parameter for a description.
Set the attribute to markerObjectClass=object_class.
nsslapd-pluginarg[1-9] Old
The equivalent plug-in-specific attribute is uniqueness-subtree-entries-oc. See this parameter for a description.
Set the attribute to requiredObjectClass=object_class.

7.2. Assigning Class of Service

A class of service definition (CoS) shares attributes between entries in a way that is transparent to applications. CoS simplifies entry management and reduces storage requirements.
Clients of the Directory Server read the attributes in a user's entry. With CoS, some attribute values may not be stored within the entry itself. Instead, these attribute values are generated by class of service logic as the entry is sent to the client application.
Each CoS is comprised of two types of entry in the directory:
  • CoS definition entry. The CoS definition entry identifies the type of CoS used. Like the role definition entry, it inherits from the LDAPsubentry object class. The CoS definition entry is below the branch at which it is effective.
  • Template entry. The CoS template entry contains a list of the shared attribute values. Changes to the template entry attribute values are automatically applied to all the entries within the scope of the CoS. A single CoS might have more than one template entry associated with it.
The CoS definition entry and template entry interact to provide attribute information to their target entries, any entry within the scope of the CoS.

7.2.1. About the CoS Definition Entry

The CoS definition entry is an instance of the cosSuperDefinition object class. The CoS definition entry also contains one of three object class that specifies the type of template entry it uses to generate the entry. The target entries which interact with the CoS share the same parent as the CoS definition entry.
There are three types of CoS, defined using three types of CoS definition entries:
  • Pointer CoS. A pointer CoS identifies the template entry using the template DN only.
  • Indirect CoS. An indirect CoS identifies the template entry using the value of one of the target entry's attributes. For example, an indirect CoS might specify the manager attribute of a target entry. The value of the manager attribute is then used to identify the template entry.
    The target entry's attribute must be single-valued and contain a DN.
  • Classic CoS. A classic CoS identifies the template entry using a combination of the template entry's base DN and the value of one of the target entry's attributes.
For more information about the object classes and attributes associated with each type of CoS, see Section 7.2.11, “Managing CoS from the Command Line”.
If the CoS logic detects that an entry contains an attribute for which the CoS is generating values, the CoS, by default, supplies the client application with the attribute value in the entry itself. However, the CoS definition entry can control this behavior.

7.2.2. About the CoS Template Entry

The CoS template entry contains the value or values of the attributes generated by the CoS logic. The CoS template entry contains a general object class of cosTemplate. The CoS template entries for a given CoS are stored in the directory tree along with the CoS definition.
The relative distinguished name (RDN) of the template entry is determined by one of the following:
  • The DN of the template entry alone. This type of template is associated with a pointer CoS definition.
  • The value of one of the target entry's attributes. The attribute used to provide the relative DN to the template entry is specified in the CoS definition entry using the cosIndirectSpecifier attribute. This type of template is associated with an indirect CoS definition.
  • By a combination of the DN of the subtree where the CoS performs a one level search for templates and the value of one of the target entry's attributes. This type of template is associated with a classic CoS definition.

7.2.3. How a Pointer CoS Works

An administrator creates a pointer CoS that shares a common postal code with all of the entries stored under dc=example,dc=com. The three entries for this CoS appear as illustrated in Figure 7.1, “Sample Pointer CoS”.
Sample Pointer CoS

Figure 7.1. Sample Pointer CoS

In this example, the template entry is identified by its DN, cn=exampleUS,cn=data, in the CoS definition entry. Each time the postalCode attribute is queried on the entry cn=wholiday,ou=people,dc=example,dc=com, the Directory Server returns the value available in the template entry cn=exampleUS,cn=data.

7.2.4. How an Indirect CoS Works

An administrator creates an indirect CoS that uses the manager attribute of the target entry to identify the template entry. The three CoS entries appear as illustrated in Figure 7.2, “Sample Indirect CoS”.
Sample Indirect CoS

Figure 7.2. Sample Indirect CoS

In this example, the target entry for William Holiday contains the indirect specifier, the manager attribute. William's manager is Carla Fuentes, so the manager attribute contains a pointer to the DN of the template entry, cn=Carla Fuentes,ou=people,dc=example,dc=com. The template entry in turn provides the departmentNumber attribute value of 318842.

7.2.5. How a Classic CoS Works

An administrator creates a classic CoS that uses a combination of the template DN and a CoS specifier to identify the template entry containing the postal code. The three CoS entries appear as illustrated in Figure 7.3, “Sample Classic CoS”:
Sample Classic CoS

Figure 7.3. Sample Classic CoS

In this example, the CoS definition entry's cosSpecifier attribute specifies the employeeType attribute. This attribute, in combination with the template DN, identify the template entry as cn=sales,cn=exampleUS,cn=data. The template entry then provides the value of the postalCode attribute to the target entry.

7.2.6. Handling Physical Attribute Values

The cosAttribute attribute contains the name of another attribute which is governed by the class of service. This attribute allows an override qualifier after the attribute value which sets how the CoS handles existing attribute values on entries when it generates attribute values.
cosAttribute: attribute_name override
There are four override qualifiers:
  • default: Only returns a generated value if there is no corresponding attribute value stored with the entry.
  • override: Always returns the value generated by the CoS, even when there is a value stored with the entry.
  • operational: Returns a generated attribute only if it is explicitly requested in the search. Operational attributes do not need to pass a schema check in order to be returned. When operational is used, it also overrides any existing attribute values.

    Note

    An attribute can only be made operational if it is defined as operational in the schema. For example, if the CoS generates a value for the description attribute, it is not possible to use the operational qualifier because this attribute is not marked operational in the schema.
  • operational-default: Only returns a generated value if there is no corresponding attribute value stored with the entry and if it is explicitly requested in the search.
If no qualifier is set, default is assumed.
For example, this pointer CoS definition entry indicates that it is associated with a template entry, cn=exampleUS,ou=data,dc=example,dc=com, that generates the value of the postalCode attribute. The override qualifier indicates that this value will take precedence over the value stored by the entries for the postalCode attribute:
dn: cn=pointerCoS,dc=example,dc=com
objectclass: top
objectclass: cosSuperDefinition
objectclass: cosPointerDefinition
cosTemplateDn: cn=exampleUS,ou=data,dc=example,dc=com
cosAttribute: postalCode override

Note

If an entry contains an attribute value generated by a CoS, the value of the attribute cannot be manually updated if it is defined with the operational or override qualifiers.
For more information about the CoS attributes, see the Red Hat Directory Server Configuration, Command, and File Reference.

7.2.7. Handling Multi-valued Attributes with CoS

Any attribute can be generated using a class of service — including multi-valued attributes. That introduces the potential for confusion. Which CoS supplies a value? Any of them or all of them? How is the value selected from competing CoS templates? Does the generated attribute use a single value or multiple values?
There are two ways to resolve this:
  • Creating a rule to merge multiple CoS-generated attributes into the target entry. This results in multiple values in the target entry.
  • Setting a priority to select one CoS value out of competing CoS definitions. This generates one single value for the target entry.

Note

Indirect CoS do not support the cosPriority attribute.
The way that the CoS handles multiple values for a CoS attribute is defined in whether it uses a merge-schemes qualifier.
cosAttribute: attribute override merge-schemes

Note

The merge-schemes qualifier does not affect how the CoS handles physical attribute values or the override qualifier. If there are multiple competing CoS templates or definitions, then the same merge-schemes and override qualifiers have to be set on every cosAttribute for every competing CoS definition. Otherwise, one combination is chosen arbitrarily from all possible CoS definitions.
Using the merge-schemes qualifier tells the CoS that it will, or can, generate multiple values for the managed attribute. There are two possible scenarios for having a multi-valued CoS attribute:
  • One CoS template entry contains multiple instances of the managed CoS attribute, resulting in multiple values on the target entry. For example:
    dn: cn=server access template,dc=example,dc=com
    objectclass: top
    objectclass: extensibleObject
    objectclass: cosTemplate
    accessTo: mail.example.com
    accessTo: irc.example.com

    Note

    This method only works with classic CoS.
  • Multiple CoS definitions may define a class of service for the same target attribute, so there are multiple template entries. For example:
    dn: cn=mail template,dc=example,dc=com
    objectclass: top
    objectclass: extensibleObject
    objectclass: cosTemplate
    accessTo: mail.example.com
    
    dn: cn=chat template,dc=example,dc=com
    objectclass: top                
    objectclass: extensibleObject
    objectclass: cosTemplate
    accessTo: irc.example.com
However, it may be that even if there are multiple CoS definitions, only one value should be generated for the attribute. If there are multiple CoS definitions, then the value is chosen arbitrarily. This is an unpredictable and unwieldy option. The way to control which CoS template to use is to set a ranking on the template — a priority — and the highest prioritized CoS always "wins" and provides the value.
It is fairly common for there to be multiple templates completing to provide a value. For example, there can be a multi-valued cosSpecifier attribute in the CoS definition entry. The template priority is set using the cosPriority attribute. This attribute represents the global priority of a particular template. A priority of zero is the highest priority.
For example, a CoS template entry for generating a department number appears as follows:
dn: cn=data,dc=example,dc=com
objectclass: top
objectclass: extensibleObject
objectclass: cosTemplate
departmentNumber: 71776
cosPriority: 0
This template entry contains the value for the departmentNumber attribute. It has a priority of zero, meaning this template takes precedence over any other conflicting templates that define a different departmentNumber value.
Templates that contain no cosPriority attribute are considered the lowest priority. Where two or more templates are considered to supply an attribute value and they have the same (or no) priority, a value is chosen arbitrarily.

Note

The behavior for negative cosPriority values is not defined in Directory Server; do not enter negative values.

7.2.8. Searches for CoS-Specified Attributes

CoS definitions provide values for attributes in entries. For example, a CoS can set the postalCode attribute for every entry in a subtree. Searches against those CoS-defined attributes, however, do not behave like searches against regular entries.
If the CoS-defined attribute is indexed with any kind of index (including presence), then any attribute with a value set by the CoS is not returned with a search. For example:
  • The postalCode attribute for Ted Morris is defined by a CoS.
  • The postalCode attribute for Barbara Jensen is set in her entry.
  • The postalCode attribute is indexed.
If an ldapsearch command uses the filter (postalCode=*), then Barbara Jensen's entry is returned, while Ted Morris's is not.
If the CoS-defined attribute is not indexed, then every matching entry is returned in a search, regardless of whether the attribute value is set locally or with CoS. For example:
  • The postalCode attribute for Ted Morris is defined by a CoS.
  • The postalCode attribute for Barbara Jensen is set in her entry.
  • The postalCode attribute is not indexed.
If an ldapsearch command uses the filter (postalCode=*), then both Barbara Jensen's and Ted Morris's entries are returned.
CoS allows for an override, an identifier given to the cosAttribute attribute in the CoS entry, which means that local values for an attribute can override the CoS value. If an override is set on the CoS, then an ldapsearch operation will return a value for an entry even if the attribute is indexed, as long as there is a local value for the entry. Other entries which possess the CoS but do not have a local value will still not be returned in the ldapsearch operation.
Because of the potential issues with running LDAP search requests on CoS-defined attributes, take care when deciding which attributes to generate using a CoS.

7.2.9. Access Control and CoS

The server controls access to attributes generated by a CoS in exactly the same way as regular stored attributes. However, access control rules depending upon the value of attributes generated by CoS will not work. This is the same restriction that applies to using CoS-generated attributes in search filters.

7.2.10. Managing CoS Using the Console

This section describes creating and editing CoS through the Directory Server Console:

7.2.10.1. Creating a New CoS

  1. In the Directory Server Console, select the Directory tab.
  2. Browse the tree in the left navigation pane, and select the parent entry for the new class of service.
  3. Go to the Object menu, and select New > Class of Service.
    Alternatively, right-click the entry and select New > Class of Service.
  4. Select General in the left pane. In the right pane, enter the name of the new class of service in the Class Name field. Enter a description of the class in the Description field.
  5. Click Attributes in the left pane. The right pane displays a list of attributes generated on the target entries.
    Click Add to browse the list of possible attributes and add them to the list.
  6. After an attribute is added to the list, a drop-down list appears in the Class of Service Behavior column.
    • Select Does not override target entry attribute to tell the directory to only return a generated value if there is no corresponding attribute value stored with the entry.
    • Select Overrides target entry attribute to make the value of the attribute generated by the CoS override the local value.
    • Select Overrides target entry attribute and is operational to make the attribute override the local value and to make the attribute operational, so that it is not visible to client applications unless explicitly requested.
    • Select Does not override target entry attribute and is operational to tell the directory to return a generated value only if there is no corresponding attribute value stored with the entry and to make the attribute operational (so that it is not visible to client applications unless explicitly requested).

    Note

    An attribute can only be made operational if it is also defined as operational in the schema. For example, if a CoS generates a value for the description attribute, you cannot select Overrides target entry attribute and is operational because this attribute is not marked operational in the schema.
  7. Click Template in the left pane. In the right pane, select how the template entry is identified.
    • By its DN. To have the template entry identified by only its DN (a pointer CoS), enter the DN of the template in the Template DN field. Click Browse to locate the DN on the local server. This will be an exact DN, such as cn=CoS template,ou=People,dc=example,dc=com.
    • Using the value of one of the target entry's attribute. To have the template entry identified by the value of one of the target entry's attributes (an indirect CoS), enter the attribute name in the Attribute Name field. Click Change to select a different attribute from the list of available attributes.
    • Using both its DN and the value of one of the target entry's attributes. To have the template entry identified by both its DN and the value of one of the target entry's attributes (a classic CoS), enter both a template DN and an attribute name. The template DN in a classic CoS is more general than for a pointer CoS; it references the suffix or subsuffix where the template entries will be. There can be more than one template for a classic CoS.
  8. Click OK.

7.2.10.2. Creating the CoS Template Entry

For a pointer CoS or a classic CoS, there must be a template entry, according to the template DN set when the class of service was created. Although the template entries can be placed anywhere in the directory as long as the cosTemplateDn attribute reflects that DN, it is best to place the template entries under the CoS itself.
  • For a pointer CoS, make sure that this entry reflects the exact DN given when the CoS was created.
  • For a classic CoS, the template DN should be recursive, pointing back to the CoS entry itself as the base suffix for the template.
  1. In the Directory Server Console, select the Directory tab.
  2. Browse the tree in the left navigation pane, and select the parent entry that contains the class of service.
    The CoS appears in the right pane with other entries.
  3. Right-click the CoS, and select New > Other.
    Alternatively, select the CoS in the right pane, click Object in the menu at the top, and select New > Other.
  4. Select cosTemplate from the list of object classes.

    Note

    The LDAPsubentry object class can be added to a new template entry. Making the CoS template entry an instance of the LDAPsubentry object class allows ordinary searches to be performed unhindered by the configuration entries. However, if the template entry already exists and is used for something else (for example, if it is a user entry), the LDAPsubentry object class does not need to be added to the template entry.
  5. Select the object classes attribute, and click Add Value.
  6. Add the extensibleObject object class. This makes it possible to add any attribute available in the directory.
  7. Click the Add Attribute button.
  8. Add the cn attribute, and give it a value that corresponds to the attribute value in the target entry. For example, if the manager attribute is used to set the value for a classic CoS, give the cn a value of a manager's DN, such as uid=bparker,ou=people,dc=example,dc=com. Alternatively, set it to a role, such as cn=QA Role,dc=example,dc=com or a regular attribute value. For example, if the employeeType attribute is selected, it can be full time or temporary.
  9. Click the Change button in the lower right corner to change the naming attribute.
  10. Use the cn of the entry as the naming attribute instead of cospriority.
  11. Click the Add Attribute button, and add the attributes listed in the CoS. The values used here will be used throughout the directory in the targeted entries.
  12. Set the cospriority. There may be more than one CoS that applies to a given attribute in an entry; the cospriority attribute ranks the importance of that particular CoS. The higher cospriority will take precedence in a conflict. The highest priority is 0.
    Templates that contain no cosPriority attribute are considered the lowest priority. In the case where two or more templates could supply an attribute value and they have the same (or no) priority, a value is chosen arbitrarily.

    Note

    The behavior for negative cosPriority values is not defined in Directory Server; do not enter negative values.

    Note

    The cosPriority attribute is not supported by indirect CoS.
The CoS is visible in the left navigation pane once there are entries beneath it. For classic CoS, there can be multiple entries, according to the different potential values of the attribute specifier.
To edit the description or attributes generated on the target entry of an existing CoS, simply double-click the CoS entry listed in the Directory tab, and make the appropriate changes in the editor window.

7.2.11. Managing CoS from the Command Line

Because all configuration information and template data is stored as entries in the directory, standard LDAP tools can be used for CoS configuration and management.

7.2.11.1. Creating the CoS Definition Entry from the Command Line

Each type of CoS requires a particular object class to be specified in the definition entry. All CoS definition object classes inherit from the LDAPsubentry object class and the cosSuperDefinition object class.
A pointer CoS uses the cosPointerDefinition object class. This object class identifies the template entry using an entry DN value specified in the cosTemplateDn attribute, as shown in Example 7.3, “An Example Pointer CoS Entry”.

Example 7.3. An Example Pointer CoS Entry

 dn: cn=pointerCoS,dc=example,dc=com
 objectclass: top 
 objectclass: cosSuperDefinition 
 objectclass: cosPointerDefinition   
 cosTemplateDn:DN_string  
 cosAttribute:list_of_attributes qualifier  
 cn: pointerCoS
An indirect CoS uses the cosIndirectDefinition object class. This type of CoS identifies the template entry based on the value of one of the target entry's attributes, as specified in the cosIndirectSpecifier attribute. This is illustrated in Example 7.4, “An Example Indirect CoS Entry”.

Example 7.4. An Example Indirect CoS Entry

 dn: cn=indirectCoS,dc=example,dc=com
 objectclass: top 
 objectclass: cosSuperDefinition 
 objectclass: cosIndirectDefinition   
 cosIndirectSpecifier:attribute_name  
 cosAttribute:list_of_attributes qualifier  
 cn: indirectCoS
A classic CoS uses the cosClassicDefinition object class. This identifies the template entry using both the template entry's DN (set in the cosTemplateDn attribute) and the value of one of the target entry's attributes (set in the cosSpecifier attribute). This is illustrated in Example 7.5, “An Example Classic CoS Entry”.

Example 7.5. An Example Classic CoS Entry

 dn: cn=classicCoS,dc=example,dc=com
 objectclass: top 
 objectclass: cosSuperDefinition 
 objectclass: cosClassicDefinition   
 cosTemplateDn:DN_string  
 cosSpecifier:attribute_name  
 cosAttribute:list_of_attributes qualifier  
 cn: classicCoS
For a class of service, the object class defines the type of CoS, and the supporting attributes identify which directory entries are affected by defining the CoS template. Every CoS has one additional attribute which can be defined for it: cosAttribute. The purpose of a CoS is to supply attribute values across multiple entries; the cosAttribute attribute defines which attribute the CoS generates values for.

7.2.11.2. Creating the CoS Template Entry from the Command Line

Each template entry is an instance of the cosTemplate object class.

Note

Consider adding the LDAPsubentry object class to a new template entry. Making the CoS template entry an instance of the LDAPsubentry object classes allows ordinary searches to be performed unhindered by the configuration entries. However, if the template entry already exists and is used for something else, such as a user entry, the LDAPsubentry object class does not need to be added to the template entry.
The CoS template entry also contains the attribute generated by the CoS (as specified in the cosAttribute attribute of the CoS definition entry) and the value for that attribute.
For example, a CoS template entry that provides a value for the postalCode attribute follows:
dn:cn=exampleUS,ou=data,dc=example,dc=com
objectclass: top
objectclass: extensibleObject
objectclass: cosTemplate
postalCode: 44438
The following sections provide examples of template entries along with examples of each type of CoS definition entry.

7.2.11.3. Example of a Pointer CoS

Example Corporation's administrator is creating a pointer CoS that shares a common postal code with all entries in the dc=example,dc=com tree.
  1. Add a new pointer CoS definition entry to the dc=example,dc=com suffix using ldapmodify:
    dn: cn=pointerCoS,dc=example,dc=com
    changetype: add
    objectclass: top
    objectclass: cosSuperDefinition
    objectclass: cosPointerDefinition
    cosTemplateDn: cn=exampleUS,ou=data,dc=example,dc=com
    cosAttribute: postalCode
  2. Create the template entry:
    dn: cn=exampleUS,ou=data,dc=example,dc=com
    changetype: add
    objectclass: top
    objectclass: extensibleObject
    objectclass: cosTemplate
    postalCode: 44438
The CoS template entry (cn=exampleUS,ou=data,dc=example,dc=com) supplies the value stored in its postalCode attribute to any entries located under the dc=example,dc=com suffix. These entries are the target entries.

7.2.11.4. Example of an Indirect CoS

This indirect CoS uses the manager attribute of the target entry to identify the CoS template entry, which varies depending on the different values of the attribute.
  1. Add a new indirect CoS definition entry to the dc=example,dc=com suffix using ldapmodify:
    dn: cn=indirectCoS,dc=example,dc=com
    changetype: add
    objectclass: top
    objectclass: cosSuperDefinition
    objectclass: cosIndirectDefinition
    cosIndirectSpecifier: manager
    cosAttribute: departmentNumber
If the directory or modify the manager entries already contain the departmentNumber attribute, then no other attribute needs to be added to the manager entries. The definition entry looks in the target suffix (the entries under dc=example,dc=com) for entries containing the manager attribute because this attribute is specified in the cosIndirectSpecifier attribute of the definition entry). It then checks the departmentNumber value in the manager entry that is listed. The value of the departmentNumber attribute will automatically be relayed to all of the manager's subordinates that have the manager attribute. The value of departmentNumber will vary depending on the department number listed in the different manager's entries.

7.2.11.5. Example of a Classic CoS

The Example Corporation administrator is creating a classic CoS that automatically generates postal codes using a combination of the template DN and the attribute specified in the cosSpecifier attribute.
  1. Add a new classic CoS definition entry to the dc=example,dc=com suffix using ldapmodify:
    dn: cn=classicCoS,dc=example,dc=com
    changetype: add
    objectclass: top
    objectclass: cosSuperDefinition
    objectclass: cosClassicDefinition
    cosTemplateDn: cn=classicCoS,dc=example,dc=com
    cosSpecifier: businessCategory
    cosAttribute: postalCode override
  2. Create the template entries for the sales and marketing departments. Add the CoS attributes to the template entry. The cn of the template sets the value of the businessCategory attribute in the target entry, and then the attributes are added or overwritten according to the value in the template:
    dn: cn=sales,cn=classicCoS,dc=example,dc=com
    changetype: add
    objectclass: top
    objectclass: extensibleObject
    objectclass: cosTemplate
    postalCode: 44438
    
    dn: cn=marketing,cn=classicCoS,dc=example,dc=com
    changetype: add
    objectclass: top
    objectclass: extensibleObject
    objectclass: cosTemplate
    postalCode: 99111
The classic CoS definition entry applies to all entries under the dc=example,dc=com suffix. Depending upon the combination of the businessCategory attribute found in the entry and the cosTemplateDn, it can arrive at one of two templates. One, the sales template, provides a postal code specific to employees in the sales department. The marketing template provides a postal code specific to employees in the marketing department.

7.2.11.6. Searching for CoS Entries

CoS definition entries are operational entries and are not returned by default with regular searches. This means that if a CoS is defined under ou=People,dc=example,dc=com, for example, the following ldapsearch command will not return them:
ldapsearch -x -s sub -b ou=People,dc=example,dc=com "(objectclass=*)"
To return the CoS definition entries, add the ldapSubEntry object class to the CoS definition entries. For example:
dn: cn=pointerCoS,ou=People,dc=example,dc=com
objectclass: top 
objectclass: cosSuperDefinition 
objectclass: cosPointerDefinition 
objectclass: ldapSubEntry 
cosTemplateDn: cn=exampleUS,ou=data,dc=example,dc=com
cosAttribute: postalCode override
Then use a special search filter, (objectclass=ldapSubEntry), with the search. This filter can be added to any other search filter using OR (|):
ldapsearch -x -s sub -b ou=People,dc=example,dc=com "(|(objectclass=*)(objectclass=ldapSubEntry))"
This search returns all regular entries in addition to CoS definition entries in the ou=People,dc=example,dc=com subtree.

Note

The Console automatically shows CoS entries.

7.2.12. Creating Role-Based Attributes

Classic CoS schemes generate attribute values for an entry based on the role possessed by the entry. For example, role-based attributes can be used to set the server look-through limit on an entry-by-entry basis.
To create a role-based attribute, use the nsRole attribute as the cosSpecifier in the CoS definition entry of a classic CoS. Because the nsRole attribute can be multi-valued, CoS schemes can be defined that have more than one possible template entry. To resolve the ambiguity of which template entry to use, include the cosPriority attribute in the CoS template entry.
For example, this CoS allows members of the manager role to exceed the standard mailbox quota. The manager role entry is:
dn: cn=ManagerRole,ou=people,dc=example,dc=com
objectclass: top
objectclass: nsRoleDefinition
objectclass: nsComplexRoleDefinition
objectclass: nsFilteredRoleDefinition
cn: ManagerRole
nsRoleFilter: ou=managers
Description: filtered role for managers

Important

The nsRoleFilter attribute cannot accept virtual attribute values.
The classic CoS definition entry looks like:
dn: cn=managerCOS,dc=example,dc=com
objectclass: top
objectclass: cosSuperDefinition
objectclass: cosClassicDefinition
cosTemplateDn: cn=managerCOS,dc=example,dc=com
cosSpecifier: nsRole
cosAttribute: mailboxquota override
The cosTemplateDn attribute provides a value that, in combination with the attribute specified in the cosSpecifier attribute (in the example, the nsRole attribute of the target entry), identifies the CoS template entry. The CoS template entry provides the value for the mailboxquota attribute. An additional qualifier of override tells the CoS to override any existing mailboxquota attributes values in the target entry.
The corresponding CoS template entry looks as follows:
dn:cn="cn=ManagerRole,ou=people,dc=example,dc=com",cn=managerCOS,dc=example,dc=com
objectclass: top
objectclass: extensibleObject
objectclass: cosTemplate
mailboxquota: 1000000
The template provides the value for the mailboxquota attribute, 1000000.

Note

The role entry and the CoS definition and template entries should be located at the same level in the directory tree.

7.3. Linking Attributes to Manage Attribute Values

A class of service dynamically supplies attribute values for entries which all have attributes with the same value, like building addresses, postal codes, or main office numbers. These are shared attribute values, which are updated in a single template entry.
Frequently, though, there are relationships between entries where there needs to be a way to express linkage between them, but the values (and possibly even the attributes) that express that relationship are different. Red Hat Directory Server provides a way to link specified attributes together, so that when one attribute in one entry is altered, a corresponding attribute on a related entry is automatically updated. (The link and managed attributes both have DN values. The value of the link attribute contains the DN of the entry for the plug-in to update; the managed attribute in the second entry has a DN value which points back to the original link entry.)

7.3.1. About Linking Attributes

The Linked Attributes Plug-in, allows multiple instances of the plug-in. Each instance configures one attribute which is manually maintained by the administrator (linkType) and one attribute which is automatically maintained by the plug-in (managedType).
Basic Linked Attribute Configuration

Figure 7.4. Basic Linked Attribute Configuration

Note

To preserve data consistency, only the plug-in process should maintain the managed attribute. Consider creating an ACI that will restrict all write access to any managed attribute. See Section 18.8, “Adding an ACI” for information on setting ACIs.
A Linked Attribute Plug-in instance can be restricted to a single subtree within the directory. This can allow more flexible customization of attribute combinations and affected entries. If no scope is set, then the plug-in operates in the entire directory.
Restricting the Linked Attribute Plug-in to a Specific Subtree

Figure 7.5. Restricting the Linked Attribute Plug-in to a Specific Subtree

When configuring the Linked Attribute Plug-in instance, certain configurations are required:
  • Both the managed attribute and linked attribute must require the Distinguished Name syntax in their attribute definitions. The linked attributes are essentially managed cross-references, and the way that the plug-in handles these cross-references is by pulling the DN of the entry from the attribute value.
    For information on planning custom schema elements, see Chapter 12, Managing the Directory Schema.
  • Each Linked Attribute Plug-in instance must be local and any managed attributes must be blocked from replication using fractional replication.
    Any changes that are made on one supplier will automatically trigger the plug-in to manage the values on the corresponding directory entries, so the data stay consistent across servers. However, the managed attributes must be maintained by the plug-in instance for the data to be consistent between the linked entries. This means that managed attribute values should be maintained solely by the plug-in processes, not the replication process, even in a multi-master replication environment.

7.3.2. Looking at the Linking Attributes Plug-in Syntax

The default Linked Attributes Plug-in entry is a container entry for each plug-in instance, similar to the password syntax plug-ins or the DNA Plug-in in the next section. Each entry beneath this container entry defines a different link-managed attribute pair.
To create a new linking attribute pair, then, create a new plug-in instance beneath the container entry. A basic linking attribute plug-in instance required defining two things:
  • The attribute that is managed manually by administrators, in the linkType attribute
  • The attribute that is created dynamically by the plug-in, in the managedType attribute
  • Optionally, a scope that restricts the plug-in to a specific part of the directory tree, in the linkScope attribute

Example 7.6. Example Linked Attributes Plug-in Instance Entry

dn: cn=Manager Link,cn=Linked Attributes,cn=plugins,cn=config
objectClass: top
objectClass: extensibleObject
cn: Manager Link
linkType: directReport
managedType: manager
linkScope: ou=people,dc=example,dc=com
All of the attributes available for an instance of the Linked Attributes Plug-in instance are listed in Table 7.2, “Linked Attributes Plug-in Instance Attributes”.

Table 7.2. Linked Attributes Plug-in Instance Attributes

Plug-in Attribute Description
cn Gives a unique name for the plug-in instance.
linkScope Contains the DN of a suffix to which to restrict the function of the plug-in instance.
linkType Gives the attribute which is maintained by an administrator. This attribute is manually maintained and is used as the reference for the plug-in. This attribute must have a DN value format. When the attribute is added, modified, or deleted, then its value contains the DN of the target entry for the plug-in to update.
managedType Gives the attribute which is maintained by the plug-in. This attribute is created and updated on target entries. This attribute must have a DN value format. When the attribute is added to the entry, its value will point back as a cross-reference to the managed entry.

7.4. Assigning and Managing Unique Numeric Attribute Values

Some entry attributes require having a unique number, such as uidNumber and gidNumber. The Directory Server can automatically generate and supply unique numbers for specified attributes using the Distributed Numeric Assignment (DNA) Plug-in.

Note

Attribute uniqueness is not necessarily preserved with the DNA Plug-in. The plug-in only assigns non-overlapping ranges, but it does allow manually-assigned numbers for its managed attributes, and it does not verify or require that the manually-assigned numbers are unique.
The issue with assigning unique numbers is not with generating the numbers but in effectively avoiding replication conflicts. The DNA Plug-in assigns unique numbers across a single back end. For multi-master replication, when each master is running a local DNA Plug-in instance, there has to be a way to ensure that each instance is using a truly unique set of numbers. This is done by assigning different ranges of numbers to each server to assign.

7.4.1. About Dynamic Number Assignments

The DNA Plug-in for a server assigns a range of available numbers that that instance can issue. The range definition is very simple and is set by two attributes: the server's next available number (the low end of the range) and its maximum value (the top end of the range). The initial bottom range is set when the plug-in instance is configured. After that, the bottom value is updated by the plug-in. By breaking the available numbers into separate ranges on each replica, the servers can all continually assign numbers without overlapping with each other.

7.4.1.2. Ranges and Assigning Numbers

There are several different ways that the Directory Server can handle generating attribute values:
  • In the simplest case, a user entry is added to the directory with an object class which requires the unique-number attribute, but without the attribute present. Adding an entry with no value for the managed attribute triggers the DNA Plug-in to assign a value. This option only works if the DNA Plug-in has been configured to assign unique values to a single attribute.
  • A similar and more manageable option is to use a magic number. This magic number is a template value for the managed attribute, something outside the server's range, a number or even a word, that the plug-in recognizes it needs to replace with a new assigned value. When an entry is added with the magic value and the entry is within the scope and filter of the configured DNA Plug-in, then using the magic number automatically triggers the plug-in to generate a new value. The following example, based on using ldapmodify, adds 0 as a magic number:
    dn: uid=jsmith,ou=people,dc=example,dc=com
     changetype: add
     objectClass: top
     objectClass: person
     objectClass: posixAccount
     uid: jsmith
     cn: John Smith
     uidNumber: 0
     gidNumber: 0
     ....
    The DNA Plug-in only generates new, unique values. If an entry is added or modified to use a specific value for an attribute controlled by the DNA Plug-in, the specified number is used; the DNA Plug-in will not overwrite it.

7.4.1.3. Multiple Attributes in the Same Range

The DNA Plug-in can assign unique numbers to a single attribute type or across multiple attribute types from a single range of unique numbers.
This provides several options for assigning unique numbers to attributes:
  • A single number assigned to a single attribute type from a single range of unique numbers.
  • The same unique number assigned to two attributes for a single entry.
  • Two different attributes assigned two different numbers from the same range of unique numbers.
In many cases, it is sufficient to have a unique number assigned per attribute type. When assigning an employeeID to a new employee entry, it is important each employee entry is assigned a unique employeeID.
However, there are cases where it may be useful to assign unique numbers from the same range of numbers to multiple attributes. For example, when assigning a uidNumber and a gidNumber to a posixAccount entry, the DNA Plug-in will assign the same number to both attributes. To do this, then pass both managed attributes to the modify operation, specifying the magic value. Using ldapmodify:
#  ldapmodify -D "cn=Directory Manager" -W -x

dn: uid=jsmith,ou=people,dc=example,dc=com
changetype: modify
add: uidNumber
uidNumber: 0
-
add:gidNumber
gidNumber: 0
When multiple attributes are handled by the DNA Plug-in, the plug-in can assign a unique value to only one of those attributes if the object class only allows one of them. For example, the posixGroup object class does not allow a uidNumber attribute but it does allow gidNumber. If the DNA Plug-in manages both uidNumber and gidNumber, then when a posixGroup entry is created, a unique number for gidNumber is assigned from the same range as the uidNumber and gidNumber attributes. Using the same pool for all attributes manged by the plug-in keeps the assignment of unique numbers aligned and prevents situations where a uidNumber and a gidNumber on different entries are assigned from different ranges and result in the same unique number.
If multiple attributes are handled by the DNA Plug-in, then the same value will be assigned to all of the given managed attributes in an entry in a single modify operation. To assign different numbers from the same range, then you must perform separate modify operations. The following example uses ldapmodify to do so:
# ldapmodify -D "cn=Directory Manager" -W -x
dn: uid=jsmith,ou=people,dc=example,dc=com
changetype: modify
add: uidNumber
uidNumber: 0
^D

# ldapmodify -D "cn=Directory Manager" -W -x
dn: uid=jsmith,ou=people,dc=example,dc=com
changetype: modify
add: employeeId
employeeId: magic

Important

When the DNA Plug-in is configured to assign unique numbers to multiple attributes, it is necessary to specify the magic value for each attribute that requires the unique number. While this is not necessary when the DNA plug-in has been configured to provide unique numbers for a single attribute, it is necessary for multiple attributes. There may be instances where an entry does not allow each type of attribute defined for the range, or, more important, an entry allow all of the attributes types defined, but only a subset of the attributes require the unique value.

Example 7.7. DNA and Unique Bank Account Numbers

Example Bank wants to use the same unique number for a customer's primaryAccount and customerID attributes. The Example Bank administrator configured the DNA Plug-in to assign unique values for both attributes from the same range.
The bank also wants to assign numbers for secondary accounts from the same range as the customer ID and primary account numbers, but these numbers cannot be the same as the primary account numbers. The Example Bank administrator configures the DNA Plug-in to also manage the secondaryAccount attribute, but will only add the secondaryAccount attribute to an entry after the entry is created and the primaryAccount and customerID attributes are assigned. This ensures that primaryAccount and customerID share the same unique number, and any secondaryAccount numbers are entirely unique but still from the same range of numbers.

7.4.2. Looking at the DNA Plug-in Syntax

The DNA Plug-in itself is a container entry, similar to the Password Storage Schemes Plug-in. Each DNA entry underneath the DNA Plug-in entry defines a new managed range for the DNA Plug-in.
To set new managed ranges for the DNA Plug-in, create entries beneath the container entry.
The most basic configuration is to set up distributed numeric assignments on a single server, meaning the ranges will not be shared or transferred between servers. A basic DNA configuration entry defines four things:
  • The attribute that value is being managed, set in the dnaType attribute
  • The entry DN to use as the base to search for entries, set in the dnaScope attribute
  • The search filter to use to identify entries to manage, set in the dnaFilter attribute
  • The next available value to assign, set in the dnaNextValue attribute (after the entry is created, this is handled by the plug-in)
For a list of attributes supported in the cn=DNA_config_entry,cn=Distributed Numeric Assignment Plugin,cn=plugins,cn=config entry, see the Red Hat Directory Server Configuration, Command, and File Reference.
To configure distributed numeric assignment on a single server for a single attribute type:
dn: cn=Account UIDs,cn=Distributed Numeric Assignment Plugin,cn=plugins,cn=config
objectClass: top
objectClass: dnaPluginConfig
cn: Account UIDs
dnatype: uidNumber
dnafilter: (objectclass=posixAccount)
dnascope: ou=people,dc=example,dc=com
dnaNextValue: 1
If multiple suppliers are configured for distributed numeric assignments, then the entry must contain the required information to transfer ranges:
  • The maximum number that the server can assign; this sets the upward bound for the range, which is logically required when multiple servers are assigning numbers. This is set in the dnaMaxValue attribute.
  • The threshold where the range is low enough to trigger a range transfer, set in the dnaThreshold attribute. If this is not set, the default value is 1.
  • A timeout period so that the server does not hang waiting for a transfer, set in the dnaRangeRequestTimeout attribute. If this is not set, the default value is 10, meaning 10 seconds.
  • A configuration entry DN which is shared among all supplier servers, which stores the range information for each supplier, set in the dnaSharedCfgDN attribute.
The specific number range which could be assigned by the server is defined in the dnaNextRange attribute. This shows the next available range for transfer and is managed automatically by the plug-in, as ranges are assigned or used by the server. This range is just "on deck." It has not yet been assigned to another server and is still available for its local Directory Server to use.
dn: cn=Account UIDs,cn=Distributed Numeric Assignment Plugin,cn=plugins,cn=config
objectClass: top
objectClass: dnaPluginConfig
cn: Account UIDs
dnatype: uidNumber
dnafilter: (objectclass=posixAccount)
dnascope: ou=People,dc=example,dc=com
dnanextvalue: 1
dnaMaxValue: 1300
dnasharedcfgdn: cn=Account UIDs,ou=Ranges,dc=example,dc=com
dnathreshold: 100
dnaRangeRequestTimeout: 60
dnaNextRange: 1301-2301
The dnaNextRange attribute should be set explicitly only if a separate, specific range has to be assigned to other servers. Any range set in the dnaNextRange attribute must be unique from the available range for the other servers to avoid duplication. If there is no request from the other servers and the server where dnaNextRange is set explicitly has reached its set dnaMaxValue, the next set of values (part of the dnaNextRange) is allocated from this deck.
The dnaNextRange allocation is also limited by the dnaThreshold attribute that is set in the DNA configuration. Any range allocated to another server for dnaNextRange cannot violate the threshold for the server, even if the range is available on the deck of dnaNextRange.

Note

If the dnaNextRange attribute is handled internally if it is not set explicitly. When it is handled automatically, the dnaMaxValue attribute serves as upper limit for the next range.
Each supplier keeps a track of its current range in a separate configuration entry which contains information about its range and its connection settings. This entry is a child of the location in dnasharedcfgdn. The configuration entry is replicated to all of the other suppliers, so each supplier can check that configuration to find a server to contact for a new range. For example:
dn: dnaHostname=ldap1.example.com+dnaPortNum=389,cn=Account UIDs,ou=Ranges,dc=example,dc=com
objectClass: dnaSharedConfig
objectClass: top
dnahostname: ldap1.example.com
dnaPortNum: 389
dnaSecurePortNum: 636
dnaRemainingValues: 1000

7.4.3. Configuring Unique Number Assignments

The unique number distribution is configured by creating different instances of the DNA Plug-in. These DNA Plug-in instances can only be created through the command line, but they can be edited through the Directory Server Console.

7.4.3.1. Configuring Unique Number Assignments

Note

Any attribute which has a unique number assigned to it must have an equality index set for it. The server must perform a sorted search, internally, to see if the dnaNextvalue is already taken, which requires an equality index on an integer attribute, with the proper ordering matching rule.
Creating indexes is described in Section 13.2, “Creating Standard Indexes”.

Note

Set up the DNA Plug-in on every supplier server, and be careful not to overlap the number range values.
  1. Create the shared container entry in the replicated subtree. The following example uses ldapmodify to do so:
    dn: ou=Ranges,dc=example,dc=coma
    changetype: add
    objectclass: top
    objectclass: extensibleObject
    objectclass: organizationalUnit
    ou: Ranges
    
    
    dn: cn=Account UIDs,ou=Ranges,dc=example,dc=coma
    changetype: add
    objectclass: top
    objectclass: extensibleObject
    cn: Account UIDs
  2. Enable the DNA Plug-in and configure it as dynamic. By default, the plug-in entry (which is the container entry) is disabled. For details on configuring dynamic plug-ins, see Section 1.9.1, “Enabling Plug-ins Dynamically”.
  3. Create the new DNA Plug-in instance beneath the container entry. For example:

    Note

    The plug-in attribute which sets which entry attributes have unique number assignments, dnaType, is multi-valued. If multiple attributes are set in the same plug-in instance, then their number assignments are taken from the same range. To use different ranges, configure different plug-in instances.
    Using ldapmodify:
    dn: cn=Account UIDs,cn=Distributed Numeric Assignment Plugin,cn=plugins,cn=config
    changetype: add
    objectClass: top
    objectClass: dnaPluginConfig
    cn: Account UIDs
    dnatype: uidNumber
    dnafilter: (objectclass=posixAccount)
    dnascope: ou=People,dc=example,dc=com
    dnanextvalue: 1
    dnaMaxValue: 1300
    dnasharedcfgdn: cn=Account UIDs,ou=Ranges,dc=example,dc=com
    dnathreshold: 100
    dnaRangeRequestTimeout: 60
    dnaMagicRegen: magic
    For a list of attributes supported in the cn=DNA_config_entry,cn=Distributed Numeric Assignment Plugin,cn=plugins,cn=config entry, see the Red Hat Directory Server Configuration, Command, and File Reference.
  4. For servers in multi-master replication, create a configuration entry for the host, which specifies its connection information and range.
    The DN of the entry is a combination of the host name and the port number (dnaHostname+dnaPortNum).
    Using ldapmodify:
    dn: dnaHostname=ldap1.example.com+dnaPortNum=389,cn=Account UIDs,ou=Ranges,dc=example,dc=com
    changetype: add
    objectClass: dnaSharedConfig
    objectClass: top
    dnahostname: ldap1.example.com
    dnaPortNum: 389
    dnaSecurePortNum: 636
    dnaRemainingValues: 1000
  5. If the server is not configured to enable dynamic plug-in, restart the server to load the new plug-in instance.
    # systemctl restart dirsrv@instance

7.4.3.2. Editing the DNA Plug-in in the Console

Note

Any attribute which has a unique number assigned to it must have an equality index set for it. The server must perform a sorted search, internally, to see if the dnaNextvalue is already taken, which requires an equality index on an integer attribute, with the proper ordering matching rule.
Creating indexes is described in Section 13.2, “Creating Standard Indexes”.
The Directory Server Console can be used to edit the DNA Plug-in instances.
  1. Click the Directory tab.
  2. Open the config folder, and then expand the plugins folder.
  3. Click the Distributed Numeric Assignment plug-in folder. All of the DNA Plug-in instances are listed in the main window.
  4. Highlight the DNA instance entry, and right-click on the Advanced link to open the property editor.
  5. Edit the DNA-related attributes.

7.4.4. Distributed Number Assignment Plug-in Performance Notes

There can be thread locking issues as DNA configuration is changed dynamically, so that new operations which access the DNA configuration (such as a DNA task or additional changes to the DNA configuration) will access the old configuration because the thread with the new configuration has not yet been released. This can cause operations to use old configuration or simply cause operations to hang.
To avoid this, preserve an interval between dynamic DNA configuration changes of 35 seconds. This means have a sleep or delay between both DNA configuration changes and any directory entry changes which would trigger a DNA plug-in operation.

Chapter 8. Organizing and Grouping Entries

Entries contained within the directory can be grouped in different ways to simplify the management of user accounts. Red Hat Directory Server supports a variety of methods for grouping entries and sharing attributes between entries. To take full advantage of the features offered by roles and class of service, determine the directory topology when planning the directory deployment.

8.1. Using Groups

Similar to the operating system, you can add users to groups in Directory Server. Groups work the other way around as roles. If you are using roles, the DN of the assigned role is stored in the nsRoleDN attribute in the user object. If you use groups, then the DN of the users who are members of this group are stored in member attributes in the group object. If you enabled the memberOf plug-in, then the groups the user is a member of, are additionally stored in memberOf attribute in the user object. With this plug-in enabled, groups additionally have the benefit of roles, that you can list the group memberships of a user, similar as when using roles. Additionally, groups are faster than roles.
For further details about using the memberOf plug-in, see Section 8.1.4, “Listing Group Membership in User Entries”.

8.1.1. Creating Static Groups in the Console

Static groups organize entries by specifying the same group value in the DN attribute of any number of users.

Note

If a user has an entry on a remote Directory Server (for example, in a chained database), different from the Directory Server which has the entry that defines the static group, then use the Referential Integrity plug-in to ensure that deleted user entries are automatically deleted from the static group.
There are some performance and access control considerations with the Referential Integrity plug-in. For more information about using referential integrity with chaining, see Section 2.3.2, “Configuring the Chaining Policy”.
  1. In the Directory Server Console, select the Directory tab.
  2. In the left pane, right-click the entry under which to add a new group, and select New > Group.
    Alternatively, go to the Object menu, and select New > Group.
  3. Click General in the left pane. Type a name for the new group in the Group Name field (the name is required), and enter a description of the new group in the Description field.
  4. Click Members in the left pane. In the right pane, select the Static Group tab. Click Add to add new members to the group.
  5. In the Search drop-down list, select what sort of entries to search for (users, groups, or both) then click Search.
  6. Select the members from the returned entries, and click OK.
  7. Click Languages in the left pane to add language-specific information for the group.
  8. Click OK to create the new group. It appears in the right pane.
To edit a static group, double-click the group entry, and make the changes in the editor window. To view the changes, go to the View menu, and select Refresh.

Note

The Console for managing static groups may not display all possible selections during a search operation if there is no VLV index for users' search. This problem occurs only when the number of users is 1000 or more and there is no VLV index for search. To work around the problem, create a VLV index for the users suffix with the filter (objectclass=person) and scope sub-tree. See Section 13.4.2, “Creating Browsing Indexes from the Command Line”.

8.1.2. Creating Dynamic Groups in the Console

Dynamic groups filter users based on their DN and include them in a single group.
  1. In the Directory Server Console, select the Directory tab.
  2. In the left pane, right-click the entry under which to add a new group, and select New > Group.
    Alternatively, go to the Object menu, and select New > Group.
  3. Click General in the left pane. Type a name for the new group in the Group Name field (the name is required), and enter a description of the new group in the Description field.
  4. Click Members in the left pane. In the right pane, select the Dynamic Group tab. Click Add to create a LDAP URL for querying the database.
  5. Enter an LDAP URL in the text field or select Construct to be guided through the construction of an LDAP URL.
    The results show the current entries (group members) which correspond to the filter.
  6. Click Languages in the left pane to add language-specific information for the group.
  7. Click OK. The new group appears in the right pane.
To edit a dynamic group, double-click the group entry to open the editor window, and make whatever changes to the dynamic group. To view the changes to the group, go to the View menu, and select Refresh.

Note

The Console for managing dynamic groups may not display all possible selections during a search operation if there is no VLV index for users' search. This problem can occur when the number of users is 1000 or more and there is no VLV index for search. To work around the problem, create a VLV index for the users suffix with the filter (objectclass=person) and scope sub-tree. See Section 13.4.2, “Creating Browsing Indexes from the Command Line”.

8.1.3. Creating Groups in the Command Line

Creating both static and dynamic groups from the command line is a similar process. A group entry contains the group name, the type of group, and a members attribute.
There are several different options for the type of group; these are described in more detail in the Red Hat Directory Server 10 Configuration, Command, and File Reference. The type of group in this case refers to the type of defining member attribute it has:
  • groupOfNames (recommended) is a simple group, that allows any entry to be added. The attribute used to determine members for this is member.
  • groupOfUniqueNames, like groupOfNames, simply lists user DNs as members, but the members must be unique. This prevents users being added more than once as a group member, which is one way of preventing self-referential group memberships. The attribute used to determine members for this is uniqueMember.
  • groupOfURLs uses a list of LDAP URLs to filter and generate its membership list. This object class is required for any dynamic group and can be used in conjunction with groupOfNames and groupOfUniqueNames.
  • groupOfCertificates is similar to groupOfURLs in that it uses an LDAP filter to search for and identify certificates (or, really, certificate names) to identify group members. This is useful for group-based access control, since the group can be given special access permissions. The attribute used to determine members for this is memberCertificate.
Table 8.1, “Dynamic and Static Group Schema” lists the default attributes for groups as they are created from the command line.

Table 8.1. Dynamic and Static Group Schema

Type of Group Group Object Classes Member Attributes
Static groupOfUniqueNames uniqueMember
Dynamic
groupOfUniqueNames
groupOfURLs
memberURL
A static group entry lists the specific members of the group. For example, using ldapmodify:
dn: cn=static group,ou=Groups,dc=example,dc=com
changetype: add
objectClass: top
objectClass: groupOfUniqueNames
cn: static group
description: Example static group.
uniqueMember: uid=mwhite,ou=People,dc=example,dc=com
uniqueMember: uid=awhite,ou=People,dc=example,dc=com
A dynamic group uses at least one LDAP URL to identify entries belonging to the group and can specify multiple LDAP URLs or, if used with another group object class like groupOfUniqueNames, can explicitly list some group members along with the dynamic LDAP URL. For example, using ldapmodify:
dn: cn=dynamic group,ou=Groups,dc=example,dc=com
changetype: add
objectClass: top
objectClass: groupOfUniqueNames
objectClass: groupOfURLs
cn: dynamic group
description: Example dynamic group.
memberURL: ldap:///dc=example,dc=com??sub?(&(objectclass=person)(cn=*sen*))

Note

The memberOf plug-in does not support dynamically generated group memberships. If you set the memberURL attribute instead of listing the group members in an attribute, the memberOf plug-in does not add the memberOf attribute to the user objects that match the filter.

8.1.4. Listing Group Membership in User Entries

The entries which belong to a group are defined, in some way, in the group entry itself. This makes it very easy to look at a group and see its members and to manage group membership centrally. However, there is no good way to find out what groups a single user belongs to. There is nothing in a user entry which indicates its memberships, as there are with roles.
The MemberOf Plug-in correlates group membership lists to the corresponding user entries.
The MemberOf Plug-in analyzes the member attribute in a group entry and automatically writes a corresponding memberOf attribute in the member's entry. (By default, this checks the member attribute, but multiple attribute instances can be used to support multiple different group types.)
As membership changes, the plug-in updates the memberOf attributes on the user entries. The MemberOf Plug-in provides a way to view the groups to which a user belongs simply by looking at the entry, including nested group membership. It can be very difficult to backtrack memberships through nested groups, but the MemberOf Plug-in shows memberships for all groups, direct and indirect.
The MemberOf Plug-in manages member attributes for static groups, not dynamic groups or circular groups.

8.1.4.1. Considerations When Using the memberOf Plug-in

This section describes important considerations when you want to use the memberOf plug-in.
Using the memberOf Plug-in in a Replication Topology
There are two approaches to manage the memberOf attribute in a replication topology:
Using the memberOf plug-in With Distributed Databases
As described in Section 2.2.1, “Creating Databases”, you can store sub-trees of your directory in individual databases. By default, the memberOf plug-in only updates user entries which are stored within the same database as the group. To enable the plug-in to also update users in different databases as the group, you must set the memberOfAllBackends parameter to on. See Section 8.1.4.4.1, “Editing the MemberOf Plug-in from the Console”.

8.1.4.2. Required Object Classes by the memberOf Plug-In

By default, the memberOf plug-in will add the nsMemberOf object class to objects to provide the memberOf attribute. This object class is safe to add to any object for this purpose, and no further action is required to enable this plug-in to operate correctly. Alternatively, you can create user objects that contain the inetUser or inetAdmin, object class. Both object classes support the memberOf attribute as well.
To configure nested groups, the group must use the extensibleObject object class.

Note

If directory entries do not contain an object class that supports the required attributes, operations fail with the following error:
LDAP: error code 65 - Object Class Violation

8.1.4.3. The MemberOf Plug-in Syntax

The MemberOf Plug-in instance defines two attributes, one for the group member attribute to poll (memberOfGroupAttr) and the other for the attribute to create and manage in the member's user entry (memberOfAttr).
The memberOfGroupAttr attribute is multi-valued. Because different types of groups use different member attributes, using multiple memberOfGroupAttr attributes allows the plug-in to manage multiple types of groups.
The plug-in instance also gives the plug-in path and function to identify the MemberOf Plug-in and contains a state setting to enable the plug-in, both of which are required for all plug-ins. The default MemberOf Plug-in is shown in Example 8.1, “Default MemberOf Plug-in Entry”.

Example 8.1. Default MemberOf Plug-in Entry

 dn: cn=MemberOf Plugin,cn=plugins,cn=config
 objectClass: top
 objectClass: nsSlapdPlugin
 objectClass: extensibleObject
 cn: MemberOf Plugin  
 nsslapd-pluginPath: libmemberof-plugin  
 nsslapd-pluginInitfunc: memberof_postop_init  
 nsslapd-pluginType: postoperation
 nsslapd-pluginEnabled: on  
 nsslapd-plugin-depends-on-type: database
 memberOfGroupAttr: member  
 memberOfGroupAttr: uniqueMember  
 memberOfAttr: memberOf  
 memberOfAllBackends: on  
 nsslapd-pluginId: memberOf
 nsslapd-pluginVersion: X.Y.Z
 nsslapd-pluginVendor: Red Hat, Inc.
 nsslapd-pluginDescription: memberOf plugin
For details about the parameters used in the example and other parameters you can set, see the MemberOf Plug-in Attributes section in the Red Hat Directory Server Command, Configuration, and File Reference.

Note

To maintain backwards compatibility with older versions of Directory Server, which only allowed a single member attribute (by default, member), it may be necessary to include the member group attribute or whatever previous member attribute was used, in addition any new member attributes used in the plug-in configuration.
 memberOfGroupAttr: member  
 memberOfGroupAttr: uniqueMember  

8.1.4.4. Configuring an Instance of the MemberOf Plug-in

The attributes defined in the MemberOf Plug-in can be changed, depending on the types of groups used in the directory.
8.1.4.4.1. Editing the MemberOf Plug-in from the Console
  1. Select the Configuration tab, and expand to the Plugins folder.
  2. Scroll to the Memberof Plugin entry.
  3. Make sure that the plug-in is enabled. This is disabled by default.
  4. Click the Advanced button to open the Advanced Properties Editor.
  5. The memberOfGroupAttr attribute sets the attribute in the group entry which the server uses to identify member entries; this attribute can be used multiple times for different group/member types. The memberOfAttr attribute sets the attribute which the plug-in creates and manages on user entries.
  6. Save the changes.
  7. If the Directory Server is not configured to enable dynamic plug-ins, restart the server to update the plug-in.
8.1.4.4.2. Editing the MemberOf Plug-in from the Command Line
  1. Enable the MemberOf Plug-in. Using ldapmodify:
    dn: cn=MemberOf Plugin,cn=plugins,cn=config
    changetype: modify
    replace: nsslapd-pluginEnabled
    nsslapd-pluginEnabled: on
  2. Set the attribute to use for the group member entry attribute. The default attribute is member, which can be changed using the replace command, or, since the memberOfGroupAttr attribute is multi-valued, additional member types can be added to the definition. For example, using ldapmodify:
    dn: cn=MemberOf Plugin,cn=plugins,cn=config
    changetype: modify
    add: memberOfGroupAttr
    memberOfGroupAttr: uniqueMember
    
    add: memberOfGroupAttr
    memberOfGroupAttr: customMember-
  3. Set the attribute to set on the user entries to show group membership. For example, using ldapmodify:
    dn: cn=MemberOf Plugin,cn=plugins,cn=config
    changetype: modify
    replace: memberOfAttr
    memberOfAttr: memberOf
  4. Optional. If the deployment uses distributed databases, then enable the memberOfAllBackends attribute to search through all databases, not just the local one, for user entries. Using ldapmodify:
    dn: cn=MemberOf Plugin,cn=plugins,cn=config
    changetype: modify
    replace: memberOfAllBackends
    memberOfAllBackends: on
  5. If the Directory Server is not configured to enable dynamic plug-ins, restart the server to load the modified new plug-in instance.

8.1.4.5. The memberOf Plug-In Shared Configuration

Replicating plug-in configuration helps maintain consistent configuration on the network, which is especially useful in large deployments. You only need to update the configuration on a master replication server, and the change is then replicated to all other servers.
The memberOf plug-in configuration can be stored in a shared configuration entry in any back end or suffix, outside of the cn=config suffix.
In the plug-in entry, the nsslapd-pluginConfigArea attribute is used to specify the location of the shared configuration:
nsslapd-pluginConfigArea: entry_DN
After you set the nsslapd-pluginConfigArea attribute to the same plug-in entry on all replicas, the replication then handles all future configuration changes.
The following table described attributes that you can use in the shared configuration entry.

Table 8.2. Attributes of the memberOf Plug-in Shared Configuration

Configuration Attribute Value Example
memberOfAttr (required) Attribute Name memberOf
memberOfGroupAttr (required) Attribute Name uniqueMember
memberOfAllBackends on|off off
memberOfEntryScope Entry DN ou=people,dc=example,dc=com
memberOfSkipNested on|off on
memberOfEntryScopeExcludeSubtree Entry DN ou=other,dc=example,dc=com
In the following example, nsslapd-pluginConfigArea is set. Therefore, the configuration in the plug-in entry is ignored.
dn: cn=MemberOf Plugin,cn=plugins,cn=config
objectClass: top
objectClass: nsSlapdPlugin
objectClass: extensibleObject
cn: MemberOf Plugin
nsslapd-pluginPath: libmemberof-plugin
nsslapd-pluginInitfunc: memberof_postop_init
nsslapd-pluginType: postoperation
nsslapd-pluginEnabled: on
nsslapd-plugin-depends-on-type: database
memberOfGroupAttr: member
memberOfAttr: memberOf
nsslapd-pluginConfigArea: cn=memberOf plugin configuration,dc=example,dc=com
In this example, the memberOf plug-in will use the uniquemember group attribute, rather than member.
dn: cn=memberOf plugin configuration,dc=example,dc=com
objectClass: top
objectClass: extensibleObject
cn: MemberOf Plugin Configuration
memberOfGroupAttr: uniquemember
memberOfAttr: memberOf

8.1.4.6. Setting the Scope of the MemberOf Plug-in

If you configured several back ends or multiple-nested suffixes, you can use the memberOfEntryScope and memberOfEntryScopeExcludeSubtree parameters to set what suffixes the MemberOf plug-in works on.
If you add a user to a group, the MemberOf plug-in only adds the memberOf attribute to the group if both the user and the group are in the plug-in's scope. For example, to configure the MemberOf plug-in to work on all entries in dc=example,dc=com, but to exclude entries in ou=private,dc=example,dc=com, set:
memberOfEntryScope: dc=example,dc=com
memberOfEntryScopeExcludeSubtree: ou=private,dc=example,dc=com
If you moved a user entry out of the scope set in the memberOfEntryScope parameter:
  • The membership attribute, such as member, is updated in the group entry to remove the user DN value.
  • The memberOf attribute is updated in the user entry to remove the group DN value.

Note

The value set in the memberOfEntryScopeExcludeSubtree parameter has a higher priority than values set in memberOfEntryScope. If the scopes set in both parameters overlap, the MemberOf plug-in only works on the non-overlapping directory entries.

8.1.4.7. Synchronizing memberOf Values

The MemberOf Plug-in automatically manages the memberOf attribute on group member entries, based on the configuration in the group entry itself. However, the memberOf attribute can be edited on a user entry directly (which is improper) or new entries can be imported or replicated over to the server that have a memberOf attribute already set. These situations create inconsistencies between the memberOf configuration managed by the server plug-in and the actual memberships defined for an entry.
Directory Server has a memberOf repair task which manually runs the plug-in to make sure the appropriate memberOf attributes are set on entries. There are three ways to trigger this task:
  • In the Directory Server Console
  • Using the fixup-memberof.pl script
  • Running a cn=memberof task,cn=tasks,cn=config tasks entry

Note

The memberOf regeneration tasks are run locally, even if the entries themselves are replicated. This means that the memberOf attributes for the entries on other servers are not updated until the updated entry is replicated.
8.1.4.7.1. Initializing and Regenerating memberOf Attributes Using fixup-memberof.pl
fixup-memberof.pl is a Perl script wrapper used to regenerate memberOf attributes as described in Section 8.1.4.7.2, “Initializing and Regenerating memberOf Attributes Using ldapmodify”.
For more details, see also man fixup-memberof.pl.
8.1.4.7.2. Initializing and Regenerating memberOf Attributes Using ldapmodify
Regenerating memberOf attributes is one of the tasks which can be managed through a special task configuration entry. Task entries occur under the cn=tasks configuration entry in the dse.ldif file, so it is also possible to initiate a task by adding the entry using ldapmodify. As soon as the task is complete, the entry is removed from the directory.
The fixup-memberof.pl script creates a special task entry in a Directory Server instance which regenerates the memberOf attributes.
To initiate a memberOf fixup task, add an entry under the cn=memberof task, cn=tasks,cn=config entry. The only required attribute is the cn for the specific task. Using ldapmodify:
dn: cn=example memberOf,cn=memberof task,cn=tasks,cn=config
changetype: add
cn:example memberOf
As soon as the task is completed, the entry is deleted from the dse.ldif configuration, so it is possible to reuse the same task entry continually.
The cn=memberof task configuration is described in more detail in the Configuration, Command, and File Reference.

8.1.5. Automatically Adding Entries to Specified Groups

Group management can be a critical factor for managing directory data, especially for clients which use Directory Server data and organization or which use groups to apply functionality to entries. Groups make it easier to apply policies consistently and reliably across the directory. Password policies, access control lists, and other rules can all be based on group membership.
Being able to assign new entries to groups, automatically, at the time that an account is created ensures that the appropriate policies and functionality are immediately applied to those entries — without requiring administrator intervention.
Dynamic groups are one method of creating groups and assigning members automatically because any matching entry is automatically included in the group. For applying Directory Server policies and settings, this is sufficient. However, LDAP applications and clients commonly need a static and explicit list of group members in order to perform whatever operation is required. And all of the members in static groups have to be manually added to those groups.
The static group itself cannot search for members like a dynamic group, but there is a way to allow a static group to have members added to it automatically — the Auto Membership Plug-in.
Automembership essentially allows a static group to act like a dynamic group, at least for adding new members to the group. Different automembership definitions create searches that are automatically run on all new directory entries. The automembership rules search for and identify matching entries — much like the dynamic search filters — and then explicitly add those entries as members to the static group.

Note

Automembership assignments are only made automatically when an entry is added to the Directory Server.
For existing entries or entries who are edited to match an automember group rule, there is a fix-up task which can be run that updates the group membership.
The Auto Membership Plug-in can target any type of object stored in the directory: users, machines and network devices, customer data, or other assets.

Note

The Auto Membership Plug-in adds a new entry to an existing group based on defined criteria. It does not create a group for the new entry.
To create a corresponding group entry when a new entry of a certain type is created, use the Managed Entries Plug-in. This is covered in Section 8.3, “Automatically Creating Dual Entries”.

8.1.5.1. Looking at the Structure of an Automembership Rule

The Auto Membership Plug-in itself is a container entry in cn=plugins,cn=config. Group assignments are defined through child entries.
8.1.5.1.1. The Automembership Configuration Entry
Automembership assignments are created through a main definition entry, a child of the Auto Membership Plug-in entry. Each definition entry defines three elements:
  • An LDAP search to identify entries, including both a search scope and a search filter (autoMemberScope and autoMemberFilter)
  • A default group to which to add the member entries (autoMemberDefaultGroup)
  • The member entry format, which is the attribute in the group entry, such as member, and the attribute value, such as dn (autoMemberGroupingAttr)
The definition is the basic configuration for an automember rule. It identifies all of the required information: what a matching member entry looks like and a group for that member to belong to.
For example, this definition assigns all Windows users to the cn=windows-users group:
dn: cn=Windows Users,cn=Auto Membership Plugin,cn=plugins,cn=config
objectclass: autoMemberDefinition
autoMemberScope: ou=People,dc=example,dc=com
autoMemberFilter: objectclass=ntUser
autoMemberDefaultGroup: cn=windows-group,cn=groups,dc=example,dc=com
autoMemberGroupingAttr: member:dn
For details about the attributes used in the example and other attributes you can set in this entry, see the cn=Auto Membership Plugin,cn=plugins,cn=config entry description in the Red Hat Directory Server Configuration, Command, and File Reference.
8.1.5.1.2. Additional Regular Expression Entries
For something like a users group, where more than likely all matching entries should be added as members, a simple definition is sufficient. However, there can be instances where entries that match the LDAP search filter should be added to different groups, depending on the value of some other attribute. For example, machines may need to be added to different groups depending on their IP address or physical location; users may need to be in different groups depending on their employee ID number.
The automember definition can use regular expressions to provide additional conditions on what entries to include or exclude from a group, and then a new, specific group to add those selected entries to.
For example, an automember definition sets all machines to be added to a generic host group.

Example 8.2. Automember Definition for a Host Group

dn: cn=Hostgroups,cn=Auto Membership Plugin,cn=plugins,cn=config
objectclass: autoMemberDefinition
cn: Hostgroups
autoMemberScope: dc=example,dc=com
autoMemberFilter: objectclass=ipHost
autoMemberDefaultGroup: cn=systems,cn=hostgroups,dc=example,dc=com
autoMemberGroupingAttr: member:dn
A regular expression rule is added so that any machine with a fully-qualified domain name within a given range is added to a web server group.

Example 8.3. Regular Expression Condition for a Web Server Group

dn: cn=webservers,cn=Hostgroups,cn=Auto Membership Plugin,cn=plugins,cn=config
objectclass: autoMemberRegexRule
description: Group for webservers
cn: webservers
autoMemberTargetGroup: cn=webservers,cn=hostgroups,dc=example,dc=com
autoMemberInclusiveRegex: fqdn=^www\.web[0-9]+\.example\.com
So, any host machine added with a fully-qualified domain name that matches the expression ^www\.web[0-9]+\.example\.com, such as www.web1.example.com, is added to the cn=webservers group, defined for that exact regular expression. Any other machine entry, which matches the LDAP filter objectclass=ipHost but with a different type of fully-qualified domain name, is added to the general host group, cn=systems, defined in the main definition entry.
The group in the definition, then, is a fallback for entries which match the general definition, but do not meet the conditions in the regular expression rule.
Regular expression rules are child entries of the automember definition.
Regular Expression Conditions

Figure 8.1. Regular Expression Conditions

Each rule can include multiple inclusion and exclusion expressions. (Exclusions are evaluated first.) If an entry matches any inclusion rule, it is added to the group.
There can be only one target group given for the regular expression rule.

Table 8.3. Regular Expression Condition Attributes

Attribute Description
autoMemberRegexRule (required object class) Identifies the entry as a regular expression rule. This entry must be a child of an automember definition (objectclass: autoMemberDefinition).
autoMemberInclusiveRegex Sets a regular expression to use to identify entries to include. Only matching entries are added to the group. Multiple regular expressions could be used, and if an entry matches any one of those expressions, it is included in the group.
The format of the expression is a Perl-compatible regular expression (PCRE). For more information on PCRE patterns, see the pcresyntax(3) man page.
This is a multi-valued attribute.
autoMemberExclusiveRegex Sets a regular expression to use to identify entries to exclude. If an entry matches the exclusion condition, then it is not included in the group. Multiple regular expressions could be used, and if an entry matches any one of those expressions, it is excluded in the group.
The format of the expression is a Perl-compatible regular expression (PCRE). For more information on PCRE patterns, see the pcresyntax(3) man page.
This is a multi-valued attribute.

Note

Exclude conditions are evaluated first and take precedence over include conditions.
autoMemberTargetGroup Sets which group to add the entry to as a member, if it meets the regular expression conditions.

8.1.5.2. Examples of Automembership Rules

Automembership rules are usually going to applied to users and to machines (although they can be applied to any type of entry). There are a handful of examples that may be useful in planning automembership rules:
  • Different host groups based on IP address
  • Windows user groups
  • Different user groups based on employee ID

Example 8.4. Host Groups by IP Address

The automember rule first defines the scope and target of the rule. The example in Section 8.1.5.1.2, “Additional Regular Expression Entries” uses the configuration group to define the fallback group and a regular expression entry to sort out matching entries.
The scope is used to find all host entries. The plug-in then iterates through the regular expression entries. If an entry matches an inclusive regular expression, then it is added to that host group. If it does not match any group, it is added to the default group.
The actual plug-in configuration entries are configured like this, for the definition entry and two regular expression entries to filter hosts into a web servers group or a mail servers group.
configuration entry
dn: cn=Hostgroups,cn=Auto Membership Plugin,cn=plugins,cn=config
objectclass: autoMemberDefinition
cn: Hostgroups
autoMemberScope: dc=example,dc=com
autoMemberFilter: objectclass=bootableDevice
autoMemberDefaultGroup: cn=orphans,cn=hostgroups,dc=example,dc=com
autoMemberGroupingAttr: member:dn

regex entry #1
dn: cn=webservers,cn=Hostgroups,cn=Auto Membership Plugin,cn=plugins,cn=config
objectclass: autoMemberRegexRule
description: Group placement for webservers
cn: webservers
autoMemberTargetGroup: cn=webservers,cn=hostgroups,dc=example,dc=com
autoMemberInclusiveRegex: fqdn=^www[0-9]+\.example\.com
autoMemberInclusiveRegex: fqdn=^web[0-9]+\.example\.com
autoMemberExclusiveRegex: fqdn=^www13\.example\.com
autoMemberExclusiveRegex: fqdn=^web13\.example\.com

regex entry #2
dn: cn=mailservers,cn=Hostgroups,cn=Auto Membership Plugin,cn=plugins,cn=config
objectclass: autoMemberRegexRule
description: Group placement for mailservers
cn: mailservers
autoMemberTargetGroup: cn=mailservers,cn=hostgroups,dc=example,dc=com
autoMemberInclusiveRegex: fqdn=^mail[0-9]+\.example\.com
autoMemberInclusiveRegex: fqdn=^smtp[0-9]+\.example\.com
autoMemberExclusiveRegex: fqdn=^mail13\.example\.com
autoMemberExclusiveRegex: fqdn=^smtp13\.example\.com

Example 8.5. Windows User Group

The basic users group shown in Section 8.1.5.1.1, “The Automembership Configuration Entry” uses the posixAccount attribute to identify all new users. All new users created within Directory Server are created with the posixAccount attribute, so that is a safe catch-all for new Directory Server users. However, when user accounts are synced over from the Windows domain to the Directory Server, the Windows user accounts are created without the posixAccount attribute.
Windows users are identified by the ntUser attribute. The basic, all-users group rule can be modified to target Windows users specifically, which can then be added to the default all-users group or to a Windows-specific group.
dn: cn=Windows Users,cn=Auto Membership Plugin,cn=plugins,cn=config
objectclass: autoMemberDefinition
autoMemberScope: dc=example,dc=com
autoMemberFilter: objectclass=ntUser
autoMemberDefaultGroup: cn=Windows Users,cn=groups,dc=example,dc=com
autoMemberGroupingAttr: member:dn

Example 8.6. User Groups by Employee Type

The Auto Membership Plug-in can work on custom attributes, which can be useful for entries which are managed by other applications. For example, a human resources application may create and then reference users based on the employee type, in a custom employeeType attribute.
Much like Example 8.4, “Host Groups by IP Address”, the user type rule uses two regular expression filters to sort full time and temporary employees, only this example uses an explicit value rather than a true regular expression. For other attributes, it may be more appropriate to use a regular expression, like basing the filter on an employee ID number range.
configuration entry
dn: cn=Employee groups,cn=Auto Membership Plugin,cn=plugins,cn=config
objectclass: autoMemberDefinition
cn: Hostgroups
autoMemberScope: ou=employees,ou=people,dc=example,dc=com
autoMemberFilter: objectclass=inetorgperson
autoMemberDefaultGroup: cn=general,cn=employee groups,ou=groups,dc=example,dc=com
autoMemberGroupingAttr: member:dn

regex entry #1
dn: cn=full time,cn=Employee groups,cn=Auto Membership Plugin,cn=plugins,cn=config
objectclass: autoMemberRegexRule
description: Group for full time employees
cn: full time
autoMemberTargetGroup: cn=full time,cn=employee groups,ou=groups,dc=example,dc=com
autoMemberInclusiveRegex: employeeType=full

regex entry #2
dn: cn=temporary,cn=Employee groups,cn=Auto Membership Plugin,cn=plugins,cn=config
objectclass: autoMemberRegexRule
description: Group placement for interns, contractors, and seasonal employees
cn: temporary
autoMemberTargetGroup: cn=temporary,cn=employee groups,ou=groups,dc=example,dc=com
autoMemberInclusiveRegex: employeeType=intern
autoMemberInclusiveRegex: employeeType=contractor
autoMemberInclusiveRegex: employeeType=seasonal

8.1.5.3. Creating Automembership Definitions

  1. If necessary, enable the Auto Membership Plug-in. Using ldapmodify:
    dn: cn=Auto Membership Plugin,cn=plugins,cn=config
    changetype: replace
    replace: nsslapd-pluginEnabled
    nsslapd-pluginEnabled: on
  2. Create the new plug-in instance below the cn=Auto Membership Plugin,cn=plugins,cn=config container entry. This entry must belong to the autoMemberDefinition object class. Using ldapmodify:
    dn: cn=Example Automember Definition,cn=Auto Membership Plugin,cn=plugins,cn=config
    objectclass: autoMemberDefinition
    ...
    The required attributes for the definition are listed in the Red Hat Directory Server Configuration, Command, and File Reference.
  3. Set the scope and filter for the definition. This is used for the initial search for matching entries.
    For example, for new entries added to the ou=People subtree and containing the ntUser attribute:
    autoMemberScope: ou=People,dc=example,dc=com
    autoMemberFilter: objectclass=ntUser
  4. Set the group to which to add matching entries (as the default or fallback group) and the format of the member entries for that group type.
    autoMemberDefaultGroup: cn=windows-group,cn=groups,dc=example,dc=com
    autoMemberGroupingAttr: member:dn
  5. Optional. Create inclusive or exclusive regular expression filters and set a group to use for entries matching those filters.
    The attributes for the regular expression condition are listed in Table 8.3, “Regular Expression Condition Attributes”.
    Regular expression conditions are added as children of the automember definition. These conditions must belong to the autoMemberRegexRule object class.
    Using ldapmodify:
    dn: cn=Example Regex,cn=Example Automember Definition,cn=Auto Membership Plugin,cn=plugins,cn=config
    objectclass: autoMemberRegexRule
    ...
    Then add the target group name and any inclusive or exclusive regular expressions. Both include and exclude conditions can be used, and multiple expressions of both types can be used.
    autoMemberTargetGroup: cn=windows-admin-group,cn=groups,dc=example,dc=com
    ​autoMemberInclusiveRegex: cn=\.* Administrator \*
    If a new entry matches a regular expression condition, it is added to that group instead of the default group set in the automember definition.
  6. If the Directory Server is not configured to enable dynamic plug-ins, restart the server to load the modified new plug-in instance.

8.1.5.4. Updating Existing Entries for Automembership Definitions

The Auto Member Plug-in only runs when new entries are added to the directory. The plug-in ignores existing entries or entries which are edited to match an automembership rule.
There is a directory task operation which can be run to check existing entries against automembership rules and then update group membership accordingly. This task (cn=automember rebuild membership) requires three elements to run, based on LDAP search parameters to identify which existing entries to process:
  • The search filter
  • The search scope
  • The base DN from which to begin the search
The specific task run also needs a name.
The task entry can be created using ldapmodify; when the task completes, the entry is automatically removed. For example:
dn: cn=my rebuild task, cn=automember rebuild membership,cn=tasks,cn=config
objectClass: top
objectClass: extensibleObject
cn: my rebuild task
basedn: dc=example,dc=com
filter: (uid=*)
scope: sub

8.1.5.5. Testing Automembership Definitions

Because each instance of the Auto Member Plug-in is a set of related-but-separate entries for the definition and regular expression, it can be difficult to see exactly how users are going to be mapped to groups. This becomes even more difficult when there are multiple rules which target different subsets of users.
There are two dry-run tasks which can be useful to determine whether all of the different Auto Member Plug-in definitions are assigning groups properly as designed.
Testing with Existing Entries

cn=automember export updates runs against existing entries in the directory and exports the results of what users would have been added to what groups, based on the rules. This is useful for testing existing rules against existing users to see how your real deployment are performing.

This task requires the same information as the cn=automember rebuild membership task — the base DN to search, search filter, and search scope — and has an additional parameter to specify an export LDIF file to record the proposed entry updates.
Using ldapmodify:
dn: cn=test export, cn=automember export updates,cn=tasks,cn=config
objectClass: top
objectClass: extensibleObject
cn: test export
basedn: dc=example,dc=com
filter: (uid=*)
scope: sub
ldif: /tmp/automember-updates.ldif
Testing with an Import LDIF

cn=automember map updates takes an import LDIF of new users and then runs the new users against the current automembership rules. This can be very useful for testing a new rule, before applying it to (real) new or existing user entries.

This is called a map task because it maps or relates changes for proposed new entries to the existing rules.
This task only requires two attributes: the location of the input LDIF (which must contain at least some user entries) and an output LDIF file to which to write the proposed entry updates. Both the input and output LDIF files are absolute paths on the local machine.
For example, using ldapmodify:
dn: cn=test mapping, cn=automember map updates,cn=tasks,cn=config
objectClass: top
objectClass: extensibleObject
cn: test mapping
ldif_in: /tmp/entries.ldif
ldif_out: /tmp/automember-updates.ldif

8.2. Using Roles

Roles are an entry grouping mechanism that unify the static and dynamic groups described in the previous sections. Roles are designed to be more efficient and easier to use for applications. For example, an application can get the list of roles of which an entry is a member by querying the entry itself, rather than selecting a group and browsing the members list of several groups.

8.2.1. About Roles

Red Hat has two kinds of groups. Static groups have a finite and defined list of members. Dynamic groups used filters to recognize which entries are members of the group, so the group membership is constantly changed as the entries which match the group filter change. (Both kinds of groups are described in Section 8.1, “Using Groups”.)
Roles are a sort of hybrid group, behaving as both a static and a dynamic group. With a group, entries are added to a group entry as members. With a role, the role attribute is added to an entry and then that attribute is used to identify members in the role entry automatically.
Role members are entries that possess the role. Members can be specified either explicitly or dynamically. How role membership is specified depends upon the type of role. Directory Server supports three types of roles:
  • Managed roles have an explicit enumerated list of members.
  • Filtered roles are assigned entries to the role depending upon the attribute contained by each entry, specified in an LDAP filter. Entries that match the filter possess the role.
  • Nested roles are roles that contain other roles.
Managed roles can do everything that can normally be done with static groups. The role members can be filtered using filtered roles, similarly to the filtering with dynamic groups. Roles are easier to use than groups, more flexible in their implementation, and reduce client complexity.
When a role is created, determine whether a user can add themselves or remove themselves from the role. See Section 8.2.10, “Using Roles Securely” for more information about roles and access control.

Note

Evaluating roles is more resource-intensive for the Directory Server than evaluating groups because the server does the work for the client application. With roles, the client application can check role membership by searching for the nsRole attribute. The nsRole attribute is a computed attribute, which identifies to which roles an entry belongs; the nsRole attribute is not stored with the entry itself. From the client application point of view, the method for checking membership is uniform and is performed on the server side.
Considerations for using roles are covered in the Red Hat Directory Server Deployment Guide.

8.2.2. Creating a Managed Role

Managed roles have an explicit enumerated list of members. Managed roles are added to entries by adding the nsRoleDN attribute to the entry.

8.2.2.1. Creating a Managed Role in the Console

  1. In the Directory Server Console, select the Directory tab.
  2. Browse the tree in the left navigation pane, and select the parent entry for the new role.
  3. Go to the Object menu, and select New > Role.
    Alternatively, right-click the entry and select New > Role.
  4. Click General in the left pane. Type a name for the new role in the Role Name field. The role name is required.
  5. Enter a description of the new role in the Description field.
  6. Click Members in the left pane.
  7. In the right pane, select Managed Role. Click Add to add new entries to the list of members.
  8. In the Search drop-down list, select Users from the Search drop-down list, then click Search. Select one of the entries returned, and click OK.
  9. After adding all of the entries, click OK.

8.2.2.2. Creating Managed Roles through the Command Line

Roles inherit from the ldapsubentry object class, which is defined in the ITU X.509 standard. In addition, each managed role requires two object classes that inherit from the nsRoleDefinition object class:
  • nsSimpleRoleDefinition
  • nsManagedRoleDefinition
A managed role also allows an optional description attribute.
Members of a managed role have the nsRoleDN attribute in their entry.
This example creates a role which can be assigned to the marketing department.
  1. Use ldapmodify with the -a option to add the managed role entry. The new entry must contain the nsManagedRoleDefinition object class, which in turn inherits from the LdapSubEntry, nsRoleDefinition, and nsSimpleRoleDefinition object classes.
    dn: cn=Marketing,ou=people,dc=example,dc=com
    objectclass: top
    objectclass: LdapSubEntry
    objectclass: nsRoleDefinition
    objectclass: nsSimpleRoleDefinition
    objectclass: nsManagedRoleDefinition
    cn: Marketing
    description: managed role for marketing staff
  2. Assign the role to the marketing staff members, one by one, using ldapmodify:
    dn: cn=Bob,ou=people,dc=example,dc=com
    changetype: modify
    add: nsRoleDN
    nsRoleDN: cn=Marketing,ou=people,dc=example,dc=com
    The nsRoleDN attribute in the entry indicates that the entry is a member of a managed role, cn=Marketing,ou=people,dc=example,dc=com.

8.2.3. Creating a Filtered Role

Entries are assigned to a filtered role depending whether the entry possesses a specific attribute defined in the role. The role definition specifies an LDAP filter for the target attributes. Entries that match the filter possess (are members of) the role.

8.2.3.1. Creating a Filtered Role in the Console

  1. In the Directory Server Console, select the Directory tab.
  2. Browse the tree in the left navigation pane, and select the parent entry for the new role.
  3. Go to the Object menu, and select New > Role.
    Alternatively, right-click the entry and select New > Role.
  4. Click General in the left pane. Type a name for the new role in the Role Name field. The role name is required.
  5. Enter a description of the new role in the Description field.
  6. Click Members in the left pane.
    A search dialog box appears briefly.
  7. In the right pane, select Filtered Role.
  8. Enter an LDAP filter in the text field, or click Construct to be guided through the construction of an LDAP filter.
    The Construct opens the standard LDAP URL construction dialog. Ignore the fields for LDAP Server Host, Port, Base DN, and Search (since the search scope cannot be set filtered role definitions).
    • Select the types of entries to filter from the For drop-down list. The entries can be users, groups, or both.
    • Select an attribute from the Where drop-down list. The two fields following it refine the search by selecting one of the qualifiers from the drop-down list, such as contains, does not contain, is, or is not. Enter an attribute value in the text box. To add additional filters, click More. To remove unnecessary filters, click Fewer.
  9. Click Test to try the filter.
  10. Click OK.

8.2.3.2. Creating a Filtered Role through the Command Line

Roles inherit from the ldapsubentry object class, which is defined in the ITU X.509 standard. In addition, each filtered role requires two object classes that inherit from the nsRoleDefinition object class:
  • nsComplexRoleDefinition
  • nsFilteredRoleDefinition
A filtered role entry also requires the nsRoleFilter attribute to define the LDAP filter to determine role members. Optionally, the role can take a description attribute.
Members of a filtered role are entries that match the filter specified in the nsRoleFilter attribute.
This example creates a filtered role which is applied to all sales managers.
  1. Run ldapmodify with the -a option to add a new entry.
  2. Create the filtered role entry.
    The role entry has the nsFilteredRoleDefinition object class, which inherits from the LdapSubEntry, nsRoleDefinition, and nsComplexRoleDefinition object classes.
    The nsRoleFilter attribute sets a filter for o (organization) attributes that contain a value of sales managers.
    dn: cn=SalesManagerFilter,ou=people,dc=example,dc=com
    changetype: add
    objectclass: top
    objectclass: LDAPsubentry
    objectclass: nsRoleDefinition
    objectclass: nsComplexRoleDefinition
    objectclass: nsFilteredRoleDefinition
    cn: SalesManagerFilter
    nsRoleFilter: o=sales managers
    Description: filtered role for sales managers
The following entry matches the filter (possesses the o attribute with the value sales managers), and, therefore, it is a member of this filtered role automatically:
dn: cn=Pat Smith,ou=people,dc=example,dc=com
objectclass: person
cn: Pat
sn: Smith
userPassword: secret
o: sales managers

8.2.4. Creating a Nested Role

Nested roles are roles that contain other roles. Before it is possible to create a nested role, another role must exist. When a nested role is created, the Console displays a list of the roles available for nesting. The roles nested within the nested role are specified using the nsRoleDN attribute.

8.2.4.1. Creating a Nested Role in the Console

  1. In the Directory Server Console, select the Directory tab.
  2. Browse the tree in the left navigation pane, and select the parent entry for the new role.
  3. Go to the Object menu, and select New > Role.
    Alternatively, right-click the entry and select New > Role.
  4. Click General in the left pane. Type a name for the new role in the Role Name field. The role name is required.
  5. Click Members in the left pane.
  6. In the right pane, select Nested Role.
  7. Click Add to add roles to the list. The members of the nested role are members of other existing roles.
  8. Select a role from the Available roles list, and click OK.

8.2.4.2. Creating Nested Role through the Command Line

Roles inherit from the ldapsubentry object class, which is defined in the ITU X.509 standard. In addition, each nested role requires two object classes that inherit from the nsRoleDefinition object class:
  • nsComplexRoleDefinition
  • nsNestedRoleDefinition
A nested role entry also requires the nsRoleDN attribute to identify the roles to nest within the container role. Optionally, the role can take a description attribute.
Members of a nested role are members of the roles specified in the nsRoleDN attributes of the nested role definition entry.
This example creates a single role out of the managed marketing role and filtered sales manager role.
  1. Run ldapmodify with the -a option to add a new entry.
  2. Create the nested role entry. The nested role has four object classes:
    • nsNestedRoleDefinition
    • LDAPsubentry (inherited)
    • nsRoleDefinition (inherited)
    • nsComplexRoleDefinition (inherited)
    The nsRoleDN attributes contain the DNs for both the marketing managed role and the sales managers filtered role.
    dn: cn=MarketingSales,ou=people,dc=example,dc=com
    objectclass: top
    objectclass: LDAPsubentry
    objectclass: nsRoleDefinition
    objectclass: nsComplexRoleDefinition
    objectclass: nsNestedRoleDefinition
    cn: MarketingSales
    nsRoleDN: cn=SalesManagerFilter,ou=people,dc=example,dc=com
    nsRoleDN: cn=Marketing,ou=people,dc=example,dc=com
Both of the users in the previous examples, Bob and Pat, are members of this new nested role.

8.2.5. Editing and Assigning Roles to an Entry

The entries which belong to a role are assigned on the role entry itself. For managed roles, user entries are added explicitly; for filtered roles, they are added through the results of an LDAP filter.
User entries are assigned to the role through the command line by editing the role entry, either by adding the entry as a member or adjusting the filter so it is included. In the Directory Server Console, however, there is a shortcut to add entries to a role by apparently editing the required user entry (but, functionally, this really edits the role entry).
  1. Select the Directory tab.
  2. In the left navigation pane, browse the tree, and select the entry for which to view or edit a role.
  3. Select Set Roles from the Object menu.
  4. Select the Managed Roles tab to display the managed roles to which this entry belongs.
  5. To add a new managed role, click Add, and select an available role from the Role Selector window.

    Note

    The configuration for a managed role associated with an entry can be edited by clicking the Edit button. The Edit Entry dialog box opens, and the general information or members for the role can be changed.
  6. Select the Other Roles tab to view the filtered or nested roles to which this entry belongs.
    Click Edit to make changes to any filtered or nested roles associated with the entry.

8.2.6. Viewing Roles for an Entry through the Command Line

Role assignments are always visible for an entry when it is displayed in the Directory Server Console. Role assignments are not returned automatically through the command line, however.
The nsRole attribute is an operational attribute. In LDAP, operational attributes must be requested explicitly. They are not returned by default with the regular attributes in the schema of the entry. You can either explicitly request single operational attributes by listing them or use + to output all operational attributes for result objects. For example, this ldapsearch command returns the list of roles of which uid=scarter is a member, in addition to the regular attributes for the entry:
# ldapsearch -D "cn=Directory Manager" -W -p 389 -h server.example.com -b "dc=example,dc=com" -s sub -x "(uid=scarter)" \* nsRole  

 dn: uid=scarter,ou=people,dc=example,dc=com
 objectClass: inetorgperson
 objectClass: top
 objectClass: person
 objectClass: organizationalPerson
 uid: scarter
 cn: Sam Carter
 sn: Carter
 givenName: Sam
 mail: scarter@example.com
 userPassword: {SSHA}6BE31mhTfcYyIQF60kWlnEL8sIvPZ59hvFTRKw==
 manager: uid=lbrown,ou=people,dc=example,dc=com
 nsRole: cn=Role for Managers,dc=example,dc=com  
 nsRole: cn=Role for Accounting,dc=example,dc=com  

Important

Be sure to use the nsRole attribute, not the nsRoleDN attribute, to evaluate role membership.

8.2.7. Making a Role Inactive or Active

The concept of activating/inactivating roles allows entire groups of entries to be activated or inactivated in just one operation. That is, the members of a role can be temporarily disabled by inactivating the role to which they belong.
When a role is inactivated, it does not mean that the user cannot bind to the server using that role entry. The meaning of an inactivated role is that the user cannot bind to the server using any of the entries that belong to that role; the entries that belong to an inactivated role will have the nsAccountLock attribute set to true.
Members of a role can be temporarily disabled by inactivating the role to which they belong. Inactivating a role inactivates the entries possessed by the role, not the role itself.
  1. Select the Directory tab.
  2. Browse the navigation tree in the left pane to locate the base DN for the role. Roles appear in the right pane with other entries.
  3. Double-click the role, open the Account tab, and click the Inactivate button.
    Alternatively, select the role. Right-click the role and select Inactivate from the menu.
The role is inactivated.
To reactivate a disabled role, re-open the role configuration or open the Object menu, and select Activate. All of the members of the role are re-enabled.

8.2.8. Viewing the Activation Status for Entries

When a nested role is inactivated, a user cannot bind to the server if it is a member of any role within the nested role. All the entries that belong to a role that directly or indirectly are members of the nested role have nsAccountLock set to true. There can be several layers of nested roles, and inactivating a nested role at any point in the nesting will inactivate all roles and users beneath it.
The Directory Server Console automatically shows the active or inactive status of entries.
To see the inactivated entries, select Inactivation State from the View menu. Members of an inactivated role have a red slash through them. For example, John Smith is a member of the inactive Example Role.
The nsAccountLock attribute is an operational attribute and must be explicitly requested in the search command in the list of search attributes or specify + to request all operational attributes. For example:
# ldapsearch -D "cn=Directory Manager" -W -p 389 -h server.example.com -b "dc=example,dc=com" -s sub -x "(uid=scarter)" nsAccountLock

8.2.9. About Deleting Roles

Deleting a role deletes the role entry but does not delete the nsRoleDN attribute for each role member. To delete the nsRoleDN attribute for each role member, enable the Referential Integrity plug-in, and configure it to manage the nsRoleDN attribute. For more information on the Referential Integrity plug-in, see Chapter 5, Maintaining Referential Integrity.

8.2.10. Using Roles Securely

Not every role is suitable for use in a security context. When creating a new role, consider how easily the role can be assigned to and removed from an entry. Sometimes it is appropriate for users to be able to add or remove themselves easily from a role. For example, if there is an interest group role called Mountain Biking, interested users should be able to add themselves or remove themselves easily.
However, it is inappropriate to have such open roles for some security situations. One potential security risk is inactivating user accounts by inactivating roles. Inactive roles have special ACIs defined for their suffix. If an administrator allows users to add and remove themselves from roles freely, then in some circumstance, they may be able to remove themselves from an inactive role to prevent their accounts from being locked.
For example, user A possesses the managed role, MR. The MR role has been locked using account inactivation. This means that user A cannot bind to the server because the nsAccountLock attribute is computed as true for that user. However, if user A was already bound to Directory Server and noticed that he is now locked through the MR role, the user can remove the nsRoleDN attribute from his entry and unlock himself if there are no ACIs preventing him.
To prevent users from removing the nsRoleDN attribute, use the following ACIs depending upon the type of role being used.
  • Managed roles. For entries that are members of a managed role, use the following ACI to prevent users from unlocking themselves by removing the appropriate nsRoleDN:
    aci: (targetattr="nsRoleDN") (targetattrfilters= add=nsRoleDN:(!(nsRoleDN=cn=AdministratorRole,dc=example,dc=com)), del=nsRoleDN:(!(nsRoleDN=cn=nsManagedDisabledRole,dc=example,dc=com))) (version3.0;acl "allow mod of nsRoleDN by self but not to critical values"; allow(write) userdn=ldap:///self;)
  • Filtered roles. The attributes that are part of the filter should be protected so that the user cannot relinquish the filtered role by modifying an attribute. The user should not be allowed to add, delete, or modify the attribute used by the filtered role. If the value of the filter attribute is computed, then all attributes that can modify the value of the filter attribute should be protected in the same way.
  • Nested roles. A nested role is comprised of filtered and managed roles, so both ACIs should be considered for modifying the attributes (nsRoleDN or something else) of the roles that comprise the nested role.
For more information about account inactivation, see Section 19.15, “Manually Inactivating Users and Roles”.

8.3. Automatically Creating Dual Entries

Some clients and integration with Red Hat Directory Server require dual entries. For example, both Posix systems typically have a group for each user. The Directory Server's Managed Entries Plug-in creates a new managed entry, with accurate and specific values for attributes, automatically whenever an appropriate origin entry is created.

8.3.1. About Managed Entries

The basic idea behind the Managed Entries Plug-in is that there are situations when Entry A is created and there should automatically be an Entry B with related attribute values. For example, when a Posix user (posixAccount entry) is created, a corresponding group entry (posixGroup entry) should also be created. An instance of the Managed Entries Plug-in identifies what entry (the origin entry) triggers the plug-in to automatically generate a new entry (the managed entry).
The plug-in works within a defined scope of the directory tree, so only entries within that subtree and that match the given search filter trigger a Managed Entries operation.
Much like configuring a class of service, a managed entry is configured through two entries:
  • A definition entry, that identifies the scope of the plug-in instance and the template to use
  • A template entry, that models what the final managed entry will look like

8.3.1.1. About the Instance Definition Entry

As with the Linked Attributes and DNA Plug-ins, the Managed Entries Plug-in has a container entry in cn=plugins,cn=config, and each unique configuration instance of the plug-in has a definition entry beneath that container.
An instance of the Managed Entries Plug-in defines three things:
  • The search criteria to identify the origin entries (using a search scope and a search filter)
  • The subtree under which to create the managed entries (the new entry location)
  • The template entry to use for the managed entries
Defining Managed Entries

Figure 8.2. Defining Managed Entries

For example:
dn: cn=Posix User-Group,cn=Managed Entries,cn=plugins,cn=config
objectclass: extensibleObject
cn: Posix User-Group
originScope: ou=people,dc=example,dc=com
originFilter: objectclass=posixAccount
managedBase: ou=groups,dc=example,dc=com
managedTemplate: cn=Posix User-Group Template,ou=Templates,dc=example,dc=com
The origin entry does not have to have any special configuration or settings to create a managed entry; it simply has to be created within the scope of the plug-in and match the given search filter.

8.3.1.2. About the Template Entry

Each instance of the plug-in uses a template entry which defines the managed entry configuration. The template effectively lays out the entry, from the object classes to the entry values.

Note

Since the template is referenced in the definition entry, it can be located anywhere in the directory. However, it is recommended that the template entry be under the replicated suffix so that any other masters in multi-master replication all use the same template for their local instances of the Managed Entries Plug-in.
The concept of a template entry is similar to the templates used in CoS, but there are some important differences. The managed entry template is slightly different than the type of template used for a class of service. For a class of service, the template contains a single attribute with a specific value that is fed into all of the entries which belong to that CoS. Any changes to the class of service are immediately reflected in the associated entries, because the CoS attributes in those entries are virtual attributes, not truly attributes set on the entry.
The template entry for the Managed Entries Plug-in, on the other hand, is not a central entry that supplies values to associated entries. It is a true template — it lays out what is in the entry. The template entry can contain both static attributes (ones with pre-defined values, similar to a CoS) and mapped attributes (attributes that pull their values or parts of values from the origin entry). The template is referenced when the managed entry is created and then any changes are applied to the managed entry only when the origin entry is changed and the template is evaluated again by the plug-in to apply those updates.
Templates, Managed Entries, and Origin Entries

Figure 8.3. Templates, Managed Entries, and Origin Entries

The template can provide a specific value for an attribute in the managed entry by using a static attribute in the template. The template can also use a value that is derived from some attribute in the origin entry, so the value may be different from entry to entry; that is a mapped attribute, because it references the attribute type in the origin entry, not a value.
A mapped value use a combination of token (dynamic values) and static values, but it can only use one token in a mapped attribute.
dn: cn=Posix User-Group Template,ou=Templates,dc=example,dc=com
objectclass: mepTemplateEntry
cn: Posix User-Group Template
mepRDNAttr: cn
mepStaticAttr: objectclass: posixGroup
mepMappedAttr: cn: $cn Group Entry
mepMappedAttr: gidNumber: $gidNumber
mepMappedAttr: memberUid: $uid
The mapped attributes in the template use tokens, prepended by a dollar sign ($), to pull in values from the origin entry and use it in the managed entry. (If a dollar sign is actually in the managed attribute value, then the dollar sign can be escaped by using two dollar signs in a row.)
A mapped attribute definition can be quoted with curly braces, such as Attr: ${cn}test. Quoting a token value is not required if the token name is not immediately followed by a character that is valid in an attribute name, such as a space or comma. For example, $cn test is acceptable in an attribute definition because a space character immediately follow the attribute name, but $cntest is not valid because the Managed Entries Plug-in attempts to look for an attribute named cntest in the origin entry. Using curly braces identifies the attribute token name.

Note

Make sure that the values given for static and mapped attributes comply with the required attribute syntax.

8.3.1.3. Entry Attributes Written by the Managed Entries Plug-in

Both the origin entry and the managed entry have special managed entries attributes which indicate that they are being managed by an instance of the Managed Entries Plug-in. For the origin entry, the plug-in adds links to associated managed entries.
dn: uid=jsmith,ou=people,dc=example,dc=com
objectclass: mepOriginEntry
objectclass: posixAccount
...
sn: Smith
mail: jsmith@example.com
mepManagedEntry: cn=jsmith Posix Group,ou=groups,dc=example,dc=com
On the managed entry, the plug-in adds attributes that point back to the origin entry, in addition to the attributes defined in the template.
dn: cn=jsmith Posix Group,ou=groups,dc=example,dc=com
objectclass: mepManagedEntry
objectclass: posixGroup
...
mepManagedBy: uid=jsmith,ou=people,dc=example,dc=com
Using special attributes to indicate managed and origin entries makes it easy to identify the related entries and to assess changes made by the Managed Entries Plug-in.

8.3.1.4. Managed Entries Plug-in and Directory Server Operations

The Managed Entries Plug-in has some impact on how the Directory Server carries out common operations, like add and delete operations.

Table 8.4. Managed Entries Plug-in and Directory Server Operations

Operation Effect by the Managed Entries Plug-in
Add With every add operation, the server checks to see if the new entry is within the scope of any Managed Entries Plug-in instance. If it meets the criteria for an origin entry, then a managed entry is created and managed entry-related attributes are added to both the origin and managed entry.
Modify
If an origin entry is modified, it triggers the plug-in to update the managed entry. Changing a template entry, however, does not update the managed entry automatically. Any changes to the template entry are not reflected in the managed entry until after the next time the origin entry is modified.
The mapped managed attributes within a managed entry cannot be modified manually, only by the Managed Entry Plug-in. Other attributes in the managed entry (including static attributes added by the Managed Entry Plug-in) can be modified manually.
Delete If an origin entry is deleted, then the Managed Entries Plug-in will also delete any managed entry associated with that entry. There are some limits on what entries can be deleted.
  • A template entry cannot be deleted if it is currently referenced by a plug-in instance definition.
  • A managed entry cannot be deleted except by the Managed Entries Plug-in.
Rename If an origin entry is renamed, then plug-in updates the corresponding managed entry. If the entry is moved out of the plug-in scope, then the managed entry is deleted, while if an entry is moved into the plug-in scope, it is treated like an add operation and a new managed entry is created. As with delete operations, there are limits on what entries can be renamed or moved.
  • A configuration definition entry cannot be moved out of the Managed Entries Plug-in container entry. If the entry is removed, that plug-in instance is inactivated.
  • If an entry is moved into the Managed Entries Plug-in container entry, then it is validated and treated as an active configuration definition.
  • A template entry cannot be renamed or moved if it is currently referenced by a plug-in instance definition.
  • A managed entry cannot be renamed or moved except by the Managed Entries Plug-in.
Replication The Managed Entries Plug-in operations are not initiated by replication updates. If an add or modify operation for an entry in the plug-in scope is replicated to another replica, that operation does not trigger the Managed Entries Plug-in instance on the replica to create or update an entry. The only way for updates for managed entries to be replicated is to replicate the final managed entry over to the replica.

8.3.2. Creating the Managed Entries Template Entry

The first entry to create is the template entry. The template entry must contain all of the configuration required for the generated, managed entry. This is done by setting the attribute-value assertions in static and mapped attributes in the template:
mepStaticAttr: attribute: specific_value
mepMappedAttr: attribute: $token_value
The static attributes set an explicit value; mapped attributes pull some value from the originating entry is used to supply the given attribute. The values of these attributes will be tokens in the form attribute: $attr. As long as the syntax of the expanded token of the attribute does not violate the required attribute syntax, then other terms and strings can be used in the attribute. For example:
mepMappedAttr: cn: Managed Group for $cn
There are some syntax rules that must be followed for the managed entries:
  • A mapped value use a combination of token (dynamic values) and static values, but it can only use one token per mapped attribute.
  • The mapped attributes in the template use tokens, prepended by a dollar sign ($), to pull in values from the origin entry and use it in the managed entry. (If a dollar sign is actually in the managed attribute value, then the dollar sign can be escaped by using two dollar signs in a row.)
  • A mapped attribute definition can be quoted with curly braces, such as Attr: ${cn}test. Quoting a token value is not required if the token name is not immediately followed by a character that is valid in an attribute name, such as a space or comma. For example, $cn test is acceptable in an attribute definition because a space character immediately follow the attribute name, but $cntest is not valid because the Managed Entries Plug-in attempts to look for an attribute named cntest in the origin entry. Using curly braces identifies the attribute token name.
  • Make sure that the values given for static and mapped attributes comply with the required attribute syntax.

Note

Make sure that the values given for static and mapped attributes comply with the required attribute syntax. For example, if one of the mapped attributes is gidNumber, then the mapped value should be an integer.

Table 8.5. Attributes for the Managed Entry Template

Attribute Description
mepTemplateEntry (object class) Identifies the entry as a template.
cn Gives the common name of the entry.
mepMappedAttr Contains an attribute-token pair that the plug-in uses to create an attribute in the managed entry with a value taken from the originating entry.
mepRDNAttr Specifies which attribute to use as the naming attribute in the managed entry. The attribute used as the RDN must be a mapped attribute for the configuration to be valid.
mepStaticAttr Contains an attribute-value pair that will be used, with that specified value, in the managed entry.
To create a template entry:
  1. Run ldapmodify to add the entry. This entry can be located anywhere in the directory tree.
    dn: cn=Posix User Template,ou=templates,dc=example,dc=com
    cn: Posix User Template
    ...
    You can also use the Directory Server Console to create the entry, as described in Section 3.2.2, “Creating Directory Entries”.
  2. Give it the mepTemplateEntry object class to indicate that it is a template entry.
    objectClass: top
    objectclass: mepTemplateEntry
    ...
  3. Set the attributes for the entry; these are described in Table 8.5, “Attributes for the Managed Entry Template”. The RDN attribute (mepRDNAttr) is required. The attribute parameters are optional and the values depend on the type of entry that the plug-in will create. Make sure that whatever attribute you use for the naming attribute is also contained in the template entry as a mapped attribute.

    Note

    Attributes which will be the same for each managed entry — like the object class for the entries — should use the mepStaticAttr attribute to set the values manually.
    mepRDNAttr: cn
    mepStaticAttr: objectclass: posixGroup
    mepMappedAttr: cn: $cn Group Entry
    mepMappedAttr: gidNumber: $gidNumber
    mepMappedAttr: memberUid: $uid

8.3.3. Creating the Managed Entries Instance Definition

Once the template entry is created, then it is possible to create a definition entry that points to that template. The definition entry is an instance of the Managed Entries Plug-in.

Note

When the definition is created, the server checks to see if the specified template entry exists. If the template does not exist, then the server returns a warning that the definition configuration is invalid.
The definition entry must define the parameters to recognize the potential origin entry and the information to create the managed entry. The attributes available for the plug-in instance are listed in Table 8.6, “Attributes for the Managed Entries Definition Entry”.

Table 8.6. Attributes for the Managed Entries Definition Entry

Attribute Name Description
originFilter The search filter to use to search for and identify the entries within the subtree which require a managed entry. The syntax is the same as a regular search filter.
originScope The base subtree which contains the potential origin entries for the plug-in to monitor.
managedTemplate Identifies the template entry to use to create the managed entry. This entry can be located anywhere in the directory tree.
managedBase The subtree under which to create the managed entries.

Note

The Managed Entries Plug-in is enabled by default. If this plug-in is disabled, then re-enable it as described in Section 1.9.2.2, “Enabling Plug-ins in the Directory Server Console”.
To create an instance:
  1. Create the new plug-in instance below the cn=Managed Entries,cn=plugins,cn=config container entry using ldapmodify.
    dn: cn=instance,cn=Managed Entries,cn=plugins,cn=config
    ...
  2. Set the scope and filter for the origin entry search, the location of the new managed entries, and the template entry to use. These required attributes are listed in Table 8.6, “Attributes for the Managed Entries Definition Entry”.
    objectClass: top
    objectClass: extensibleObject
    cn: Posix User-Group
    originScope: ou=people,dc=example,dc=com
    originFilter: objectclass=posixAccount
    managedBase: ou=groups,dc=example,dc=com
    managedTemplate: cn=Posix User-Group Template,ou=Templates,dc=example,dc=com
  3. If the Directory Server is not configured to enable dynamic plug-ins, restart the server to load the modified new plug-in instance.

8.3.4. Putting Managed Entries Plug-in Configuration in a Replicated Database

As Section 8.3.1, “About Managed Entries” highlights, different instances of the Managed Entries Plug-in are created as children beneath the container plug-in entry in cn=plugins,cn=com. (This is common for plug-ins which allow multiple instances.) The drawback to this is that the configuration entries in cn=plugins,cn=com are not replicated, so the configuration has to be re-created on each Directory Server instance.
The Managed Entries Plug-in entry allows the nsslapd-pluginConfigArea attribute. This attribute to another container entry, in the main database area, which contains the plug-in instance entries. This container entry can be in a replicated database, which allows the plug-in configuration to be replicated.
  1. Using ldapmodify, create a container entry in a subtree that is replicated.
    dn: cn=managed entries container,ou=containers,dc=example,dc=com
    objectclass: top
    objectClass: extensibleObject
    objectClass: nsContainer
    cn: managed entries container
  2. Using ldapmodify, add the nsslapd-pluginConfigArea attribute to the Managed Entries Plug-in entry that points back to the container entry.
    dn: cn=Managed Entries,cn=plugins,cn=config
    changetype: modify
    add: nsslapd-pluginConfigArea
    nsslapd-pluginConfigArea: cn=managed entries container,ou=containers,dc=example,dc=com

8.4. Using Views

Virtual directory tree views, or views, create a virtual directory hierarchy, so it is easy to navigate entries, without having to make sure those entries physically exist in any particular place. The view uses information about the entries to place them in the view hierarchy, similarly to members of a filtered role or a dynamic group. Views superimpose a DIT hierarchy over a set of entries, and to client applications, views appear as ordinary container hierarchies.

8.4.1. About Views

Views create a directory tree similar to the regular hierarchy, such as using organizational unit entries for subtrees, but views entries have an additional object class (nsview) and a filter attribute (nsviewfilter) that set up a filter for the entries which belong in that view. Once the view container entry is added, all of the entries that match the view filter instantly populate the view. The target entries only appear to exist in the view; their true location never changes. For example, a view may be created as ou=Location Views, and a filter is set for l=Mountain View. Every entry, such as cn=Jane Smith,l=Mountain View,ou=People,dc=example,dc=com, is immediately listed under the ou=Location Views entry, but the real cn=Jane Smith entry remains in the ou=People,dc=example,dc=com subtree.
A Directory Tree with a Virtual DIT View hierarchy

Figure 8.4. A Directory Tree with a Virtual DIT View hierarchy

Virtual DIT views behave like normal DITs in that a subtree or a one-level search can be performed with the expected results being returned.

Note

There is a sample LDIF file with example views entries, Example-views.ldif, installed with Directory Server. This file is in the /usr/share/dirsrv/data/ directory on Red Hat Enterprise Linux 7. The sections in this chapter assume Example-views.ldif is imported to the server.
The Red Hat Directory Server Deployment Guide has more information on how to integrate views with the directory tree hierarchy.

8.4.2. Creating Views in the Console

  1. Select the Directory tab.
  2. In the left navigation tree, create an organizational unit suffix to hold the views. For instance, for views based on the locality (l) attribute, name this organizational unit Location Views. Creating sub suffixes is described in Section 2.1.1.2, “Creating a New Sub Suffix Using the Console”.
  3. Right-click ou=Location Views, and select New > Other.
  4. Select nsview from the New Object menu, and click OK.
  5. In the Property Editor window, click the Add Value button, and add the organization unit object class.
  6. Name the organization unit according to how to organize the views. For instance, ou=Sunnyvale. Make the ou attribute the naming attribute.
  7. Click the Add Attribute button, and add the nsviewfilter attribute.
  8. Create a filter that reflects the views, such as (l=Sunnyvale).
  9. Click the Change button in the lower right corner to change the naming attribute.
    Use the ou of the entry as the naming attribute instead of description.
  10. Click OK to close the attributes box, and click OK again to save the new view entry.
The new view is immediately populated with any entries matching the search filter, and any new entries added to directory are automatically included in the view.

8.4.3. Creating Views from the Command Line

  1. Use the ldapmodify utility to bind to the server and prepare it to add the new view entry to the configuration file.
  2. Assuming the view container ou=Location Views,dc=example,dc=com from the Example-views.ldif file is in the Directory Server, add the new views container entry, in this example, under the dc=example,dc=com root suffix. This entry must have the nsview object class and the nsViewFilter attribute. The nsViewFilter attribute sets the attribute-value which identifies entries that belong in the view.
    dn: ou=Mountain View,ou=Location Views,dc=example,dc=com
    changetype: add
    objectClass: top
    objectClass: organizationalUnit
    objectClass: nsview
    ou: Mountain View
    nsViewFilter: l=Mountain View
    description: views categorized by location

8.4.4. Improving Views Performance

As Section 8.4.1, “About Views” describes, views are derived from search results based on a given filter. Part of the filter is the attribute defined in the nsViewFilter attribute; the rest of the filter is based on the entry hierarchy, looking for the entryid and parentid of the real entries included in the view.
(|(parentid=search_base_id)(entryid=search_base_id)
If any of the searched-for attributes — entryid, parentid, or the attribute set in nsViewFilter — are not indexed, then the views search becomes an unindexed search because the views operation searches the entire tree for matching entries.
To improve views performance, create equality indexes for entryid, parentid, and the attribute set in nsViewFilter.
Creating equality indexes is covered in Section 13.2, “Creating Standard Indexes”, and updating existing indexes to include new attributes is covered in Section 13.3, “Generating New Indexes to Existing Databases”.

Chapter 9. Configuring Secure Connections

By default, clients and users connect to the Red Hat Directory Server over a standard connection. Standard connections do not use any encryption, so information is sent back and forth between the server and client in the clear.
Directory Server supports TLS connections, StartTLS connection, and SASL authentication, which provide layers of encryption and security that protect directory data from being read even if it is intercepted.

9.1. Requiring Secure Connections

Directory Server provides the following ways of using encrypted connections:
LDAPS
When you use the LDAPS protocol, the connection starts using encryption and either succeeds or fails. However, no unencrypted data is ever send over the network. For this reason, prefer LDAPS instead of using StartTLS over unencrypted LDAP.
StartTLS over LDAP
Clients establish an unencrypted connection over the LDAP protocol and then send the StartTLS command. If the command succeeds, all further communication is encrypted.

Warning

If the StartTLS command fails and the client does not cancel the connection, all further data, including authentication information, is sent unencrypted over the network.
SASL
Simple Authentication and Security Layer (SASL) enables you to authenticate a user using external authentication methods, such as Kerberos. For details, see Section 9.9, “Setting up SASL Identity Mapping”.

9.2. Setting a Minimum Strength Factor

For additional security, the Directory Server can be configured to require a certain level of encryption before it allows a connection. The Directory Server can define and require a specific Security Strength Factor (SFF) for any connection. The SSF sets a minimum encryption level, defined by its key strength, for any connection or operation.
To require a minimum SSF for any and all directory operations, set the nsslapd-minssf configuration attribute. When enforcing a minimum SSF, Directory Server looks at each available encryption type for an operation — TLS or SASL — and determines which has the higher SSF value and then compares the higher value to the minimum SSF. It is possible for both SASL authentication and TLS to be configured for some server-to-server connections, such as replication.

Note

Alternatively, use the nsslapd-minssf-exclude-rootdse configuration attribute. This sets a minimum SSF setting for all connections to the Directory Server except for queries against the root DSE. A client may need to obtain information about the server configuration, like its default naming context, before initiating an operation. The nsslapd-minssf-exclude-rootdse attribute allows the client to get that information without having to establish a secure connection first.
The SSF for a connection is evaluated when the first operation is initiated on a connection. This allows StartTLS and SASL binds to succeed, even though those two connections initially open a regular connection. After the TLS or SASL session is opened, then the SSF is evaluated. Any connection which does not meet the SSF requirements is closed with an LDAP unwilling to perform error.
Set a minimum SSF to disable insecure connections to a directory.

Warning

If you connect to the directory using the unencrypted LDAP protocol without SASL, the first LDAP message can contain the bind request. In this case, the credentials are sent unencrypted over the network before the server cancels the connection, because the SSF did not met the minimum value set.
Use the LDAPS protocol or SASL binds to ensure that the credentials are never sent unencrypted.
The default nsslapd-minssf attribute value is 0, which means there is no minimum SSF for server connections. The value can be set to any reasonable positive integer. The value represents the required key strength for any secure connection.
The following example adds the nsslapd-minssf attribute to the cn=config entry:
# ldapmodify -D "cn=Directory Manager" -W -x

dn: cn=config
changetype: modify
replace: nsslapd-minssf
nsslapd-minssf: 128

Note

An ACI can be set to require an SSF for a specific type of operation, as in Section 18.13.2.4, “Requiring a Certain Level of Security in Connections”.
Secure connections can be required for bind operations by turning on the nsslapd-require-secure-binds attribute, as in Section 19.11.1, “Requiring Secure Binds”.

9.3. Managing the NSS Database Used by Directory Server

When you set up TLS encryption or certificate-based authentication, you must manage the certificates which are stored in a Network Security Services (NSS). This section describes the most frequent actions about managing the Directory Server's NSS database.

9.3.1. Creating the NSS Database for a Directory Server Instance

Directory Server stores the certificates in an NSS database in the /etc/dirsrv/slapd-instance_name/ directory. Before you can manage the certificates, you must create the database.

Note

For security reasons, Red Hat recommends setting a strong password on the database.

9.3.1.1. Creating the NSS Database Using the Command Line

To create the NSS database using the command line:
  1. Create the NSS database and set a password:
    # certutil -d /etc/dirsrv/slapd-instance_name/ -N
    Enter a password which will be used to encrypt your keys.
    The password should be at least 8 characters long,
    and should contain at least one non-alphabetic character.
    
    Enter new password:
    Re-enter password:
  2. Set the permissions:
    # chown dirsrv:dirsrv /etc/dirsrv/slapd-instance_name/*.db
    # chown dirsrv:dirsrv /etc/dirsrv/slapd-instance_name/pkcs11.txt
    # chmod 600 /etc/dirsrv/slapd-instance_name/*.db
    # chmod 600 /etc/dirsrv/slapd-instance_name/pkcs11.txt

9.3.1.2. Creating the NSS Database Using the Console

Directory Server automatically creates the NSS database when you open the Manage Certificates task entry in the Directory Server Console the first time.
To open the Manage Certificates task entry:
  1. Open the Directory Server Console.
  2. On the Tasks tab, click Manage Certificates, and set a password to protect the database.

9.3.2. Creating a Certificate Signing Request

The Certificate Signing Request (CSR) is a request to the Certificate Authority (CA) to sign the key of the server. This section describes how to create the CSR including the private key.

9.3.2.1. Creating a Certificate Signing Request Using the Command Line

To create the key and a CSR, use the certutil utility:
# certutil -d instance_directory -R -g key_size -a \
     -o output_file -8 FQDN -s "certificate_subject"
For example, to generate a 4096 bit private key for the server.example.com host and to store the CSR in the /root/instance_name.csr file:
# certutil -d /etc/dirsrv/slapd-instance_name/ -R -g 4096 -a \
     -o /root/instance_name.csr -8 server.example.com \
     -s "CN=server.example.com,O=example_organization,OU=IT,ST=North Carolina,C=US"
The string specified in the -s parameter must be a valid subject name according to RFC 1485. The CN field is required, and you must set it to the Fully-qualified Domain Name (FQDN) of the server. The other fields are optional.
For further details about using certutil, see the certutil(1) man page.
After you generated the CSR, submit it to the CA to get a certificate issued. For further details, see your CA's documentation.

9.3.2.2. Creating a Certificate Signing Request Using the Console

To create the keys and a CSR using the Console:
  1. Open the Directory Server Console.
  2. On the Tasks tab, click Manage Certificates.
  3. On the Server Certs tab, click the Request button.
  4. Select if you want to request the certificate manually or from one of the displayed CAs and click Next.
  5. Enter the requested information and click Next.

    Important

    Enter the Fully-qualified Domain Name (FQDN) of the server into the Server name field.
  6. Select the key size and signing algorithm. Click Next.
    For security reasons:
    • an RSA key size of 2048 bits or higher
    • a strong signing algorithm, such as SHA-256 or higher
  7. Enter the password of the Network Security Services (NSS) database and click Done.
    If you use an Hardware Security Module (HSM) to store the certificates, the device is plugged in, and the module has been installed as described in Section 9.7, “Using Hardware Security Modules”, then the module is available in the Active Encryption Token menu.
  8. Copy the CSR to the clipboard or save it into a file.
  9. Click Done.
After you generated the CSR, submit it to the CA to get a certificate issued. For further details, see your CA's documentation.

9.3.3. Installing a CA Certificate

To enable Directory Server to trust the Certificate Authority (CA) you must install the certificate of the CA into the Network Security Services (NSS) database. During this process, you must set which certificates issued by the CA should be trusted:

Table 9.1. CA Trust Options

Console Option certutil Option Description
Accepting connections from clients (Client Authentication) T,, The server trusts this CA certificate for issuing client certificates suitable for TLS EXTERNAL binds.
Accepting connections to other servers (Server Authentication) C,, The server verifies that certificates, used to establish an encrypted connection to a replication partner, have been issued by a trusted CA.
You can set both options for a CA. When you use certutil, pass the -T "CT,," parameter to the utility.

9.3.3.1. Installing a CA Certificate Using the Command Line

To install a CA certificate in the Directory Server's NSS database, use the certutil utility. For example, to import the CA certificate stored in the /etc/pki/CA/nss/ca.crt file:
# certutil -d /etc/dirsrv/slapd-instance_name/ -A -n "certificate_nickname" \
     -t "C,," -i /etc/pki/CA/nss/ca.crt
The -t trust_options parameter sets which certificates issued by the CA should be trusted. See Table 9.1, “CA Trust Options”.
For further details about the parameters used in the previous command, see the certutil(1) man page.

9.3.3.2. Installing a CA Certificate Using the Console

To install a CA certificate using the Directory Server Console:
  1. Open the Directory Server Console.
  2. On the Tasks tab, click Manage Certificates.
  3. Select the CA Certs tab and click the Install button.
  4. Either select the file that contains the server certificate or paste the certificate into the field. Click Next.
  5. Verify the certificate details and click Next.
  6. Verify the certificate nickname and click Next.
  7. Set which certificates issued by the CA should be trusted. You can select one or both of the options. See Table 9.1, “CA Trust Options”.

9.3.4. Installing a Certificate

After the Certificate Authority (CA) issued the requested certificate, you must install it in the Network Security Services (NSS) database.

9.3.4.1. Installing a Server Certificate Using the Command Line

To install a server certificate in the Directory Server's NSS database, use the certutil utility. For example:
  1. Install the CA certificate. See Section 9.3.3, “Installing a CA Certificate”.
  2. Import the certificate. For example to import the certificate stored in the /root/instance_name.crt file:
    # certutil -d /etc/dirsrv/slapd-instance_name/ -A \
         -n "server-cert" -t ",," -a -i /root/instance_name.crt
  3. Optionally, verify the certificate:
    # certutil -d /etc/dirsrv/slapd-instance_name/ -V -n "server-cert" -u V
For further details about the parameters used in the previous certutil commands, see the certutil(1) man page.

9.3.4.2. Installing a Certificate Using the Console

To install a server certificate using the Console:
  1. Install the CA certificate. See Section 9.3.3, “Installing a CA Certificate”.
  2. Open the Directory Server Console.
  3. On the Tasks tab, click Manage Certificates.
  4. Click the Install button.
  5. Select the file that contains the server certificate or, alternatively, paste the certificate into the field. Click Next.
  6. Verify the certificate details and click Next.
  7. Set a certificate nickname and click Next.

    Note

    The Directory Server Console does not support installing a certificate that uses the same nickname as an existing one. To work around the problem, install the certificate using the command line. See Section 9.3.4.1, “Installing a Server Certificate Using the Command Line”.
  8. Enter the password of the NSS database and click Done.

9.3.5. Generating and Installing a Self-signed Certificate

In certain situations, administrators want to use a self-signed certificate for encrypted connections to Directory Server.

Note

You can only perform this operation using the command line.
To create and install a self-signed certificate:
  1. Verify if the Network Security Services (NSS) database is already initialized:
    # certutil -d /etc/dirsrv/slapd-instance_name -L
    If the command fails, initalize the database. For details, see Section 9.3.1, “Creating the NSS Database for a Directory Server Instance”.
  2. Generate a noise file with random data. For example, to generate a file with a size of 4096 bits:
    # openssl rand -out /tmp/noise.bin 4096
  3. Create the self-signed certificate and add it to the NSS database:
    # certutil -S -x -d /etc/dirsrv/slapd-instance_name/ -z /tmp/noise.bin \
         -n "server-cert" -s "CN=$HOSTNAME" -t "CT,C,C" -m $RANDOM \
         --keyUsage digitalSignature,nonRepudiation,keyEncipherment,dataEncipherment
    Red Hat Enterprise Linux automatically replaces the $HOSTNAME variable with the Fully-qualified Domain Name (FQDN) and $RANDOM with a randomly-generated number. For further details about the parameters used in the previous commands, see the certutil(1) man page.
  4. Optionally, verify that the generated certificate is self-signed:
    # certutil -L -d /etc/dirsrv/slapd-instance_name/ -n "server-cert" | egrep "Issuer|Subject"
            Issuer: "CN=server.example.com"
            Subject: "CN=server.example.com"
    The output of this command must display the FQDN of the Directory Server host for both the issuer and subject of the certificate.

9.3.6. Renewing a Certificate

If a certificate will expire in the near future, you must renew it in time to continue establishing secure connections.

9.3.6.1. Renewing a Certificate Using the Command Line

To renew a certificate:
  1. Create a new Certificate Signing Request (CSR) with the same options, such as key size, host name, and subject. For details about creating a CSR, see Section 9.3.2.1, “Creating a Certificate Signing Request Using the Command Line”
  2. After you received the issued certificate from your CA, install it in the database using the same nickname. See Section 9.3.3.1, “Installing a CA Certificate Using the Command Line”.
Directory Server will automatically use the newer issued certificate.

9.3.6.2. Renewing a Certificate Using the Console

The process for renewing is similar to generating a Certificate Signing Request (CSR). Follow the procedure in Section 9.3.3.2, “Installing a CA Certificate Using the Console”, but click the Renew instead of the Request button in the Manage Certificates task.

9.3.7. Removing a Certificate

If a certificate is no longer needed, for example, because it has been exposed, remove it from the database.

9.3.7.1. Removing a Certificate Using the Command Line

To remove a certificate using the command line:
  1. Remove the private key. See Section 9.3.8, “Removing a Private Key”.
  2. Optionally, display the certificates in the database:
    # certutil -d /etc/dirsrv/slapd-instance_name/ -L
    Certificate Nickname                     Trust Attributes
                                             SSL,S/MIME,JAR/XPI
    
    Example CA                               CT,,
    server-cert                              u,u,u
    
  3. Remove the certificate. For example, to remove the certificate with the server-cert nickname:
    # certutil -d /etc/dirsrv/slapd-instance_name/ -D -n "server-cert"

9.3.7.2. Removing a Certificate Using the Console

To remove a certificate using the Console:
  1. Open the Directory Server Console.
  2. On the Tasks tab, click Manage Certificates.
  3. On the Server Certs tab, select the certificate and click the Delete button.
  4. Click Yes to confirm.

9.3.8. Removing a Private Key

If a private key is no longer needed, for example, because you created a stronger key, remove it from the database.

Warning

If you remove a private key, certificates based on this key are no longer working.

9.3.8.1. Removing a Private Key Using the Command Line

To remove a private key:
  1. Remove all certificates based on the key you want to delete. See Section 9.3.7, “Removing a Certificate”.
  2. Optionally, display the keys in the database:
    # certutil -d /etc/dirsrv/slapd-instance_name/ -K
    certutil: Checking token "NSS Certificate DB" in slot "NSS User Private Key and Certificate Services"
    Enter Password or Pin for "NSS Certificate DB":
    < 0> rsa      7a2fb6c269d83c4036eac7e4edb6aaf2ed08bc4a   server-cert
    < 1> rsa      662b826aa3dd4ca7fd7e6883558cf3866c42f4e2   example-cert
  3. Remove the private key. For example, to remove the private key with the example-cert nickname:
    # certutil -d /etc/dirsrv/slapd-instance_name/ -F -n "example-cert"

9.3.8.2. Removing a Private Key Using the Console

Removing a private key using the Console is not supported. However, if you request a new certificate using the Console according to Section 9.3.2.2, “Creating a Certificate Signing Request Using the Console”, the Console automatically generates a new private key and uses it.

9.3.9. Changing the CA Trust Options

In certain situations you need to update the trust option of a Certificate Authority (CA). This section describes this procedure.

9.3.9.1. Changing the CA Trust Options Using the Command Line

To change the trust options of a CA, pass the new options in the -t parameter to the certutil utility.
For example, to set that Directory Server trusts only client authentication certificates issued by the CA named example-CA:
# certutil -d /etc/dirsrv/slapd-instance_name/ -M -t "T,," -n "example-CA"
The -t trust_options parameter sets which certificates issued by the CA should be trusted. See Table 9.1, “CA Trust Options”.
For further details about the parameters and trust options, see the certutil(1) man page.

9.3.9.2. Changing the CA Trust Options Using the Console

To change the trust options of a CA using the Console:
  1. Open the Directory Server Console.
  2. On the Tasks tab, click Manage Certificates.
  3. Select the CA Certs tab.
  4. Select the CA to edit, click the Edit Trust button, and set which certificates issued by the CA should be trusted. You can select one or both of the options. See Table 9.1, “CA Trust Options”.

9.3.10. Changing the Password of the NSS Database

In certain situations, administrators want to change the password of the Network Security Services (NSS) database. This section describes this process.

Important

If you use a password file to enable Directory Server to automatically open the Network Security Services (NSS) database, you must update the file after you set the new password. See Section 9.4.1.5, “Creating a Password File for Directory Server”.

9.3.10.1. Changing the Password of the NSS Database Using the Command Line

To change the password of the NSS database:
# certutil -d /etc/dirsrv/slapd-instance_name -W
Enter Password or Pin for "NSS Certificate DB":
Enter a password which will be used to encrypt your keys.
The password should be at least 8 characters long,
and should contain at least one non-alphabetic character.

Enter new password: 
Re-enter password: 
Password changed successfully.

9.3.10.2. Changing the Password of the NSS Database Using the Console

To change the password of the NSS database using the Console:
  1. Open the Directory Server Console.
  2. On the Tasks tab, click Manage Certificates.
  3. Click the Change Password button.
  4. Enter the current and the new password and click OK

9.3.11. Adding a Certificate Revocation List

If a Certificate Authority (CA) revokes a certificate, the CA adds the certificate to its Certificate Revocation Lists (CRL). Directory Server can use this list to identify which certificates are no longer trusted by the CA and to deny access.

9.3.11.1. Adding a Certificate Revocation List Using the Command Line

To add a CRL using certutil, pass the -4 URL_to_CRL_file parameter to the utility when you install the CA certificate.
For details about installing a CA certificate, see Section 9.3.3.1, “Installing a CA Certificate Using the Command Line”.

9.3.11.2. Adding a Certificate Revocation List Using the Console

To add a CRL using the Console:
  1. Open the Directory Server Console.
  2. On the Tasks tab, click Manage Certificates.
  3. Select the Revoked Certs tab and click the Add button.
  4. Enter the path to the file, select the list format, and click OK.

9.4. Enabling TLS

Directory Server supports encrypted connections between clients and the server, as well as between servers in a replication environment. For this, Directory Server supports:
  • The LDAPS protocol: TLS encryption is used directly after the connection has been established.
  • The STARTTLS command over the LDAP protocol: The connection is unencrypted until the client sends the STARTTLS command.

Important

For security reasons, Red Hat recommends enabling TLS encryption.
You can use TLS with simple authentication using a bind Distinguished Name (DN) and password, or using certificate-based authentication.
Directory Server's cryptographic services are provided by Mozilla Network Security Services (NSS), a library of TLS and base cryptographic functions. NSS includes a software-based cryptographic token which is Federal Information Processing Standard (FIPS) 140-2 certified.

9.4.1. Enabling TLS in Directory Server

This section describes how to enable TLS in Directory Server.

9.4.1.1. Enabling TLS in Directory Server Using the Command Line

To enable TLS using the command line:
  1. Verify if the NSS database for Directory Server already exists:
    # ls -1 /etc/dirsrv/slapd-instance_name/*.db
    Create the databases if they do not exist. See Section 9.3.1.1, “Creating the NSS Database Using the Command Line”.
  2. Request and install the certificate:
  3. Enable TLS and set the LDAPS port:
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    dn: cn=config
    changetype: modify
    replace: nsslapd-securePort
    nsslapd-securePort: 636
    -
    replace: nsslapd-security
    nsslapd-security: on
  4. Display the nickname of the server certificate in the NSS database:
    # certutil -L -d /etc/dirsrv/slapd-instance_name/
    Certificate Nickname                Trust Attributes
                                        SSL,S/MIME,JAR/XPI
    
    Example CA                          CT,,
    server-cert                         u,u,u
    You need the nickname in the next step.
  5. To enable the RSA cipher family, setting the NSS database security device, and the server certificate nickname, add the following entry to the directory:
    # ldapadd -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    dn: cn=RSA,cn=encryption,cn=config
    cn: RSA
    objectClass: top
    objectClass: nsEncryptionModule
    nsSSLToken: internal (software)
    nsSSLPersonalitySSL: server-cert
    nsSSLActivation: on

    Note

    By default, the name of the security device in the NSS database is internal (software).
    If the previous command fails, because the cn=RSA,cn=encryption,cn=config entry already exists, update the corresponding attributes:
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    dn: cn=RSA,cn=encryption,cn=config
    changetype: modify
    replace: nsSSLToken
    nsSSLToken: internal (software)
    -
    replace: nsSSLPersonalitySSL
    nsSSLPersonalitySSL: server-cert
    -
    replace: nsSSLActivation
    nsSSLActivation: on
  6. Optionally, update the list of ciphers Directory Server supports. For details, see Section 9.4.1.3.1, “Displaying and Setting the Ciphers Used by Directory Server Using the Command Line”.
  7. Optionally, enable certificate-based authentication. For details, see Section 9.8, “Using Certificate-based Client Authentication”.
  8. Optionally, create a password file to enable Directory Server to start without prompting for the password of the NSS database. For details, see Section 9.4.1.5, “Creating a Password File for Directory Server”.
  9. Restart the Directory Server instance:
    # systemctl restart dirsrv@instance_name
    If you set a password on the NSS database and did not create a password file, Directory Server prompts for the password of the NSS database. For details, see Section 9.4.1.4, “Starting Directory Server Without a Password File”.
  10. Optionally, enable the Directory Server Console to use TLS when connecting to the server. See Section 9.4.2.1, “Enabling TLS for Connections from the Console to Directory Server Using the Command Line”.
  11. Optionally, enable TLS for the Red Hat Identity Management Console to use TLS. See Section 9.4.3, “Enabling TLS in the Administration Server”.

9.4.1.2. Enabling TLS in Directory Server Using the Console

To enable TLS in Directory Server using the Console:
  1. Import the Certificate Authority (CA) certificate. See Section 9.3.3.2, “Installing a CA Certificate Using the Console”.
  2. Import the server certificate issued by the CA. See Section 9.3.4.2, “Installing a Certificate Using the Console”.
  3. Open the Directory Server Console and select the host name on the Configuration tab.
  4. On the Settings tab in the right pane, enter the LDAPS port into the Encrypted port field and click the Save button.
    The default port for LDAPS is 636.

    Note

    The LDAPS port must be different to the one set for unencrypted connections in the Port field.
  5. On the Encryption tab in the right pane:
    1. Select Enable SSL for this server.
    2. Enable Use this cipher family: RSA, select the security device and certificate from the list.
    3. Optionally, click the Settings button to update the list of ciphers Directory Server supports. For details, see Section 9.4.1.3.2, “Displaying and Setting the Ciphers Used by Directory Server Using the Console”.
    4. Optionally, enable users to authenticate using certificates. For details, see Section 9.8, “Using Certificate-based Client Authentication”.

      Important

      If TLS is only enabled in Directory Server and not in the Directory Server Console, do not select Require client authentication.
    5. Select the Check host name against name in certificate for outbound SSL connections option to verify that the host name matches the cn attribute in the subject name of the certificate the client presents to the server for authentication.

      Important

      Red Hat recommends enabling this option in a replication environment to protect outgoing TLS connections against a man-in-the-middle attack (MITM).
    6. Make sure that the Use SSL in Console option is not selected.

      Warning

      Do not enable the Use SSL in Console option before you finished this procedure, because it takes effect immediately after you save the setting. As a consequence, the Console fails to connect to the server.
      If you accidentally enabled this option and the Console fails to connect to the server, disable the option using the command line:
      # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
      dn: cn=slapd-instance_name,cn=Red Hat Directory Server,
       cn=Server Group,cn=server.example.com,ou=example.com,o=NetscapeRoot
      changetype: modify
      replace: nsServerSecurity
      nsServerSecurity: off
    7. Click Save.
  6. Optionally, create a password file to enable Directory Server to start without prompting for the password of the NSS database. For details, see Section 9.4.1.5, “Creating a Password File for Directory Server”.
  7. Restart the Directory Server instance:
    # systemctl restart dirsrv@instance_name
    If you set a password on the NSS database and did not create a password file, Directory Server prompts for the password of the NSS database. For details, see Section 9.4.1.4, “Starting Directory Server Without a Password File”.
  8. Optionally, enable the Directory Server Console to use TLS when connecting to the server. See Section 9.4.2.2, “Enabling TLS for Connections from the Console to Directory Server Using the Console”.
  9. Optionally, enable that the Red Hat Identity Management Console uses TLS. See Section 9.4.3, “Enabling TLS in the Administration Server”.

9.4.1.3. Setting Encryption Ciphers

Directory Server supports different ciphers, and you can enable or disable them. A cipher is the algorithm used in encryption. When a client initiates a TLS connection with a server, the client tells the server what ciphers it prefers to encrypt information. If the server supports at least one of these ciphers, the encrypted connection can be established using this algorithm.
If you enabled encryption according to Section 9.4, “Enabling TLS”, you can display and update the ciphers Directory Server uses.
9.4.1.3.1. Displaying and Setting the Ciphers Used by Directory Server Using the Command Line

Displaying all Available Ciphers

To display the list of all available ciphers supported in Directory Server:
# ldapsearch -xLLL -H ldap://server.example.com:389 -D "cn=Directory Manager" -W \
     -b 'cn=encryption,cn=config' -s base nsSSLSupportedCiphers -o ldif-wrap=no

dn: cn=encryption,cn=config
nsSSLSupportedCiphers: TLS_ECDHE_ECDSA_WITH_AES_128_GCM_SHA256::AES-GCM::AEAD::128
...
nsSSLSupportedCiphers: SSL_CK_RC2_128_CBC_EXPORT40_WITH_MD5::RC2::MD5::128
This is only a list of available ciphers you can enable or disable. The list does not display the ciphers Directory Server currently uses.

Displaying the Ciphers Directory Server Uses

The ciphers Directory Server currently uses are stored in the nsSSLEnabledCiphers read-only attribute. To display them:
# ldapsearch -xLLL -H ldap://server.example.com:389 -D "cn=Directory Manager" -W \
     -b 'cn=encryption,cn=config' -s base nsSSLEnabledCiphers -o ldif-wrap=no

dn: cn=encryption,cn=config
nsSSLEnabledCiphers: TLS_RSA_WITH_AES_256_CBC_SHA::AES::SHA1::256
nsSSLEnabledCiphers: TLS_RSA_WITH_AES_128_CBC_SHA::AES::SHA1::128
...
Additionally, you can display the ciphers which are configured to be enabled and disabled:
# ldapsearch -xLLL -H ldap://server.example.com:389 -D "cn=Directory Manager" -W \
     -b 'cn=encryption,cn=config' -s base nsSSL3Ciphers -o ldif-wrap=no

dn: cn=encryption,cn=config
nsSSL3Ciphers: -all,+tls_rsa_aes_128_sha,+tls_rsa_aes_256_sha,...

Important

Directory Server uses the settings from the nsSSL3Ciphers attribute to generate the list of ciphers which are actually used. However, if you enabled weak ciphers in nsSSL3Ciphers, but set the allowWeakCiphers parameter to off, which is the default, Directory Server only uses the strong ciphers and displays them in the nsSSLSupportedCiphers read-only attribute.

Updating the List of Enabled Ciphers

To update the list of enabled ciphers:
  1. Display the list of currently enabled ciphers. See the section called “Displaying the Ciphers Directory Server Uses”.
  2. To enable only specific ciphers, update the nsSSL3Ciphers attribute. For example, to enable only the TLS_RSA_WITH_AES_128_GCM_SHA256 cipher:
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn: cn=encryption,cn=config
    changetype: modify
    add: nsSSL3Ciphers
    nsSSL3Ciphers: -all,+TLS_RSA_WITH_AES_128_GCM_SHA256
  3. Restart the Directory Server instance:
    # systemctl restart dirsrv@instance_name
  4. Optionally, display the list of enabled ciphers to verify the result. See the section called “Displaying the Ciphers Directory Server Uses”.
9.4.1.3.2. Displaying and Setting the Ciphers Used by Directory Server Using the Console
To select and optionally update the ciphers using the Console:
  1. Open the Directory Server Console.
  2. On the Configuration tab, select the server name.
  3. Select the Encryption tab in the right pane and click the Settings button.
  4. Optionally, update the list of ciphers. For example:
  5. Click OK.
  6. Click Save.
  7. If you updated the list of ciphers, restart the Directory Server instance:
    # systemctl restart dirsrv@instance_name

9.4.1.4. Starting Directory Server Without a Password File

If you start Directory Server with encryption enabled and a password set on the NSS database:
  • If the ns-slapd Directory Server process is started by the systemctl command, systemd prompts for the password and automatically passes the input to the systemd-tty-ask-password-agent utility. For example:
    # systemctl start dirsrv
    Enter PIN for Internal (Software) Token:
  • In rare cases, when the ns-slapd Directory Server process is not started by the systemctl utility and is detached from the terminal, a message is send to all terminals using the wall command. For example:
    Broadcast message from root@server (Fri 2017-01-01 06:00:00 CET):
    
    Password entry required for 'Enter PIN for Internal (Software) Token:' (PID 1234).
    Please enter password with the systemd-tty-ask-password-agent tool!
    To enter the password, run:
    # systemd-tty-ask-password-agent
    Enter PIN for Internal (Software) Token:

9.4.1.5. Creating a Password File for Directory Server

If encryption is enabled and a password set on the NSS database, Directory Server prompts for this password when the service starts. See Section 9.4.1.4, “Starting Directory Server Without a Password File”.
To bypass this prompt, you can store the NSS database password in the /etc/dirsrv/slapd-instance_name/pin.txt file. This enables Directory Server to start automatically without prompting for this password.

Warning

The password is stored in clear text. Do not use a password file if the server is running in an unsecured environment.
To create the password file:
  1. Create the /etc/dirsrv/slapd-instance_name/pin.txt file with the following content:
    • If you use the NSS software cryptography module, which is the default:
      Internal (Software) Token:password
    • If you use a Hardware Security Module (HSM):
      name_of_the_token:password
  2. Set the permissions:
    # chown dirsrv:dirsrv /etc/dirsrv/slapd-instance_name/pin.txt
    # chmod 400 /etc/dirsrv/slapd-instance_name/pin.txt

9.4.1.6. Managing How Directory Server Behaves If the Certificate Has Been Expired

By default, if encryption is enabled and the certificate has expired, Directory Server logs a warning and the service starts. To change this behavior, set the nsslapd-validate-cert attribute in the cn=config entry. You can set it to the following values:
  • warn: The Directory Server instance starts and log a warning about the expired certificate into the /var/log/dirsrv/slapd-instance_name/error log file. This is the default setting.
  • on: Directory Server validates the certificate and the instance fails to start if the certificate has expired.
  • off: Directory Server does not validate the certificate expiration date. The instance starts and no warning will be logged.

Example 9.1. Preventing Directory Server to Start If the Certificate Has Been Expired

To prevent Directory Server from starting if the certificate has expired:
  1. Set the nsslapd-validate-cert attribute to on:
    # ldapmodify -D "cn=Directory Manager" -W -p 636 -h server.example.com -x
    dn: cn=config
    changetype: modify
    replace: nsslapd-validate-cert
    nsslapd-validate-cert: on
  2. Restart the Directory Server instance:
    # systemctl restart dirsrv@instance_name

9.4.2. Enabling TLS for Connections from the Console to Directory Server

This section describes how you configure the Directory Server Console to use TLS to access the directory.

Important

Before you can enable TLS in the Console, enable encryption in Directory Server according to Section 9.4.1, “Enabling TLS in Directory Server” and restart the instance.
To configure an encrypted connection to the Red Hat Identity Management Console, see Section 9.4.3, “Enabling TLS in the Administration Server”.

9.4.2.1. Enabling TLS for Connections from the Console to Directory Server Using the Command Line

To enable TLS for connections from the Console to Directory Server:
# ldapmodify -D "cn=Directory Manager" -W -p 636 -h server.example.com -x
dn: cn=slapd-instance_name,cn=Red Hat Directory Server,
 cn=Server Group,cn=server.example.com,ou=example.com,o=NetscapeRoot
changetype: modify
replace: nsServerSecurity
nsServerSecurity: on
When you start the Console the next time, it automatically uses TLS for connections to Directory Server.

9.4.2.2. Enabling TLS for Connections from the Console to Directory Server Using the Console

To enable TLS for connections from the Console to Directory Server:
  1. Open the Directory Server Console and select the host name on the Configuration tab.
  2. On the Encryption tab in the right pane:
    1. Select Use SSL in the Console.
    2. Click Save
  3. Restart the Directory Server Console.

9.4.3. Enabling TLS in the Administration Server

This section describes how to:
  • Enable the HTTPS protocol when connecting to the Red Hat Identity Management Console application
  • Set that the Administration Server stores its data in the o=NetscapeRoot entry using an encrypted connection to Directory Server
  • Enable the Red Hat Identity Management Console application to use the LDAPS protocol to manage users and groups stored in the directory

Important

Before you can enable these features, enable encryption in Directory Server according to Section 9.4.1, “Enabling TLS in Directory Server” and restart the instance.
To enable TLS in the Administration Server:
  1. Import the required certificates. Select one of the following ways:
    The Administration Server and Directory Server must share at least one CA certificate to trust the other's non-shared certificates.
  2. Open the Administration Server Console.
  3. On the Configuration tab, select the Administration Server entry in the left pane.
  4. Select the Encryption tab in the right pane to enable encryption for the Red Hat Identity Management Console:
    1. Select Enable SSL for this server.
    2. Enable Use this cipher family: RSA, select the security device and certificate from the list.
    3. Optionally, click the Settings button to update the list of ciphers the Administration Server supports.
    4. Optionally, enable client authentication using certificates. For details, see Section 9.8, “Using Certificate-based Client Authentication”.
    5. Click Save.
  5. Select the Configuration DS tab in the right pane to configure that the Administration Server stores its data in the o=NetscapeRoot entry using the LDAP protocol:
    1. Set the LDAPS port of the Directory Server instance that stores the o=NetscapeRoot entry. By default, LDAPS uses the 636 port.
    2. Select Secure Connection.
    3. Click Save.
  6. Select the User DS tab in the right pane to configure that the Red Hat Identity Management Console uses an encrypted connection to manage users and groups:
    1. Select Set User Directory and fill the fields. For encrypted connections, the Secure Connections option must be selected and the port port specified in the LDAP Host and Port field must support LDAPS.
    2. Click Save.
  7. Optionally, set the minimum and maximum TLS version for connections from the Console to the server in the ~/.redhat-idm-console/Console.version.Login.preferences file. For example:
    sslVersionMin: TLS1.1
    sslVersionMax: TLS1.2
  8. Optionally, create a password file to enable the Administration Server to start without prompting for the password of the Network Security Services (NSS) database. For details, see Section E.2.7.3, “Creating a Password File for the Administration Server”.
  9. Restart the Administration Server:
    # systemctl restart dirsrv-admin
    If you did not create a password file, the system prompts for the password of the NSS database.
  10. To configure that the Console trusts the certificate, see Section 9.4.3.1, “Managing Certificates Used by the Directory Server Console”.
After you completed this procedure, you can connect to the Red Hat Identity Management Console using the HTTPS protocol. For example:
# redhat-idm-console -a https://server.example.com:9830

9.4.3.1. Managing Certificates Used by the Directory Server Console

The certificates and keys used by the server are stored in NSS security databases in the /etc/dirsrv/slapd-instance_name/ directory. The Directory Server Console itself also uses certificates and keys for TLS connections; these certificates are stored in a separate database in the user's home directory. If the Directory Server Console is used to connect to multiple instances of Directory Server over TLS, then it is necessary to trust every CA which issued the certificates for every Directory Server instance.
When TLS is enabled for the Directory Server Console, the Directory Server Console must have a copy of the issuing CA certificate for it to trust the server's client certificates. Otherwise, the Console will return errors about not trusting the CA which issued the certificate.

Note

Only the CA certificates for the CA which issued the server's certificate is required. The Directory Server Console does not require its own client certificate.

Importing a CA Certificate When Using the Console on Linux

For example, to add the CA certificate stored in the /root/ca.crt file to the database:
# certutil -d ~/.redhat-idm-console/ -A -n "Example CA" -t CT,, -a -i /root/ca.crt

Importing a CA Certificate When Using the Console on Windows

For example, to add the CA certificate stored in the C:\ca.crt file to the database:
> cd C:\Program Files\Red Hat Identity Management Console\
> certutil.exe -d "C:\Documents and Settings\user_name\.389-console\" -A -n "Example CA" -t CT,, -a -i C:\ca.crt

9.5. Displaying the Encryption Protocols Enabled in Directory Server

To display the enabled encryption protocols in Directory Server:
# ldapsearch -D "cn=Directory Manager" -W -p 389 -h server.example.com -x \
     -s base -b 'cn=encryption,cn=config' sslVersionMin sslVersionMax

dn: cn=encryption,cn=config
sslVersionMin: TLS1.0
sslVersionMax: TLS1.2
The sslVersionMin and sslVersionMax parameter control which encryption protocol versions Directory Server uses. By default, only TLS 1.0 and later versions of the protocol are enabled.

Important

For security reasons, none of the parameters should be set to the insecure SSL2 or SSL3 protocol versions.

9.6. Setting the Encryption Protocol Versions

Update the sslVersionMin and sslVersionMax parameters to set which encryption protocols Directory Server uses.

Important

To always use the strongest supported encryption protocol version in the sslVersionMax parameter, do not set this parameter. See Section 9.6.1, “Automatically Using the Strongest Protocol in the sslVersionMax Parameter”.
For example, to enable only TLS 1.1 and 1.2:
  1. Update the sslVersionMin and sslVersionMax parameters:
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    dn: cn=encryption,cn=config
    changetype: modify
    replace: sslVersionMin
    sslVersionMin: TLS1.1
    -
    replace: sslVersionMax
    sslVersionMax: TLS1.2
    
  2. Restart the Directory Server instance:
    # systemctl restart dirsrv@instance_name

9.6.1. Automatically Using the Strongest Protocol in the sslVersionMax Parameter

If the sslVersionMax parameter is not set, which is the default, Directory Server uses the strongest supported encryption protocol version for this parameter. This enables you to always have the strongest protocol version enabled after an update.

Identifying if sslVersionMax is Not Set

Even if sslVersionMax is not set, the parameter is returned in a search. To identify if the parameter is not set:
# grep sslVersionMax /etc/dirsrv/slapd-instance_name/dse.ldif
If the command displays no output, the parameter is not set and uses the default, which is the strongest supported encryption protocol.

Removing the sslVersionMax Parameter

Remove the sslVersionMax parameter to use its default setting:
  1. Remove the sslVersionMax parameter:
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    dn: cn=encryption,cn=config
    changetype: modify
    delete: sslVersionMax
  2. Restart the Directory Server instance:
    # systemctl restart dirsrv@instance_name

9.7. Using Hardware Security Modules

A security module serves as a medium between the Directory Server and the TLS layer. The module stores the keys and certificates used for encryption and decryption. The standard which defines these modules is Public Key Cryptography Standard (PKCS) #11, so these modules are PKCS#11 modules.
By default, Directory Server uses built-in security databases, key3.db and cert8.db, to store the keys and certificates used by the servers.
It is also possible to use external security devices to store Directory Server certificates and keys. For Directory Server to use an external PKCS#11 module, the module's drivers must be installed in Directory Server.
For more information, consult the documentation for your hardware security module.

9.8. Using Certificate-based Client Authentication

Directory Server supports certificate-based authentication of LDAP clients and for server-to-server connection, such as replication.
Depending on the configuration, the client can or must authenticate using a certificate, if you enabled certificate-based authentication. After verifying the certificate, the server searches for the user in the directory, based on the attributes in the subject field of the certiticate. If the search return exactly one user entry, Directory Server uses this user for all further operations. Optionally, you can configure that the certifiate used for authentication must match the Distinguished Encoding Rules (DER)-formatted certificate stored in the userCertificate attribute of the user.
Benefits of using certificate-based authentication:
  • Improved efficiency. When using applications that prompt once for the certificate database password and then use that certificate for all subsequent bind or authentication operations, it is more efficient than continuously providing a bind DN and password.
  • Improved security. The use of certificate-based authentication is more secure than non-certificate bind operations because certificate-based authentication uses public-key cryptography. Bind credentials cannot be intercepted across the network. If the certificate or device is lost, it is useless without the PIN, so it is immune from third-party interference like phishing attacks.

9.8.1. Setting up Certificate-based Authentication

To enable certificate-based authentication:
  1. Enable encrypted connections. For details, see Section 9.4, “Enabling TLS”.
  2. Install the CA certificate and set the trust options for client and server connections. See Section 9.3.3, “Installing a CA Certificate”.
  3. Optionally, verify that the CT,, trust options for client and server are set for the CA certificate:
    # certutil -d /etc/dirsrv/slapd-instance_name/ -L
    Certificate Nickname                Trust Attributes
                                        SSL,S/MIME,JAR/XPI
    
    Example CA                          CT,,
  4. Create the /etc/dirsrv/slapd-instance_name/certmap.conf file to map information from the certificate to Directory Server users. For example:
    certmap default         default
    default:DNComps         dc
    default:FilterComps     mail,cn
    default:VerifyCert      on
    
    certmap example         o=Example Inc.,c=US
    example:DNComps
    This configures that for authenticating users who use a certificate that has the o=Example Inc.,c=US issuer Distinguished Name (DN) set, Directory Server does not generate a base DN from the subject of the certificate, because the DNComps parameter is set empty for this issuer. Additionally, the settings for the FilterComps and VerifyCert are inherited from the default entry.
    Certificates that have a different issuer DN than the specified one will use the settings from the default entry and generate the base DN based on the cn attributes in the subject of the certificate. This enables Directory Server to start the search under a specific DN, without searching the whole directory.
    For all certificates, Directory Server generates the search filter using the mail and the cn attribute from the certificate's subject. However, if the mail does not exist in the subject, Directory Server will automatically use the value of the certificate's e attribute in the subject.
    For further details and descriptions of the available parameters, see the description of the certmap.conf file in the Red Hat Directory Server Configuration, Command, and File Reference.
  5. Enable client authentication. For example, to configure that client authentication is optional:
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x -Z
    
    dn: cn=encryption,cn=config
    changetype: modify
    replace: nsSSLClientAuth
    nsSSLClientAuth: allowed
    Alternatively, set the nsSSLClientAuth parameter to required to configure that clients must use a certificate to authenticate.

    Important

    The Directory Server Console does not support client authentication. If you set nsSSLClientAuth to required, you cannot use the Console to manage the instance.
  6. If you enabled that the authenticating certificate must match the one stored in the userCertificate attribute of the user by setting alias_name:VerifyCert on in the /etc/dirsrv/slapd-instance_name/certmap.conf file, add the certificates to the user entries. See Section 9.8.2, “Adding a Certificate to a User”.

9.8.2. Adding a Certificate to a User

When you set up certificate-based authentication, you can set that the certificate used to authenticate must match the one stored in the userCertificate binary attribute of the user. If you enabled this feature by setting alias_name:VerifyCert on in the /etc/dirsrv/slapd-instance_name/certmap.conf file, you must add the certificate of the affected users to their directory entry.

Important

You must store the certificate in the Distinguished Encoding Rules (DER) format in the userCertificate attribute.
To store a certificate in the userCertificate attribute of a user:
  1. If the certificate is not DER-formatted, convert it. For example:
    # openssl x509 -in /root/certificate.pem -out /root/certificate.der -outform DER
  2. Add the certificate to the user's userCertificate attribute. For example:
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn: uid=user_name,ou=People,dc=example,dc=com
    changetype: modify
    add: userCertificate
    userCertificate: < /root/example.der
For further details about using binary attributes, see Section 3.1.8, “Using Binary Attributes”.

9.8.3. Forcing the EXTERNAL SASL Mechanism for Bind Requests

At the beginning of a TLS session, the client sends its certificate to the server. Then, it sends its bind request. Most clients issue the bind request using the EXTERNAL SASL mechanism, which signals Directory Server that it needs to use the identity in the certificate for the bind, instead of the credentials in the bind request.
However, if a client uses simple authentication or anonymous credentials, this information is missing. In this case, the TLS session fails with invalid credentials, even if the certificate and the client identity in the certificate was valid.
To configure that Directory Server forces clients to use the EXTERNAL SASL mechanism and to ignore any other bind method in the request:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
dn: cn=config
changetype: modify
replace: nsslapd-force-sasl-external
nsslapd-force-sasl-external: on

9.8.4. Authenticating Using a Certificate

To use the OpenLDAP client tools, to authenticate to a Directory Server instance that supports authentication using a certificate:
  1. Set the following environment variables to the corresponding paths for the CA certificate, the user key, and the user certificate. For example:
    LDAPTLS_CACERTFILE=/home/user_name/CA.crt
    LDAPTLS_KEYFILE=/home/user_name/user.key
    LDAPTLS_CERTFILE=/home/user_name/user.crt
    Alternatively, set the TLS_CACERT, TLS_KEY, and TLS_CERT parameters in the ~/.ldaprc file. For details, see the TLS OPTIONS section in the ldap.conf(5) man page.
  2. Connect to the server. For example:
    # ldapwhoami -H ldaps://server.example.com:636
If you use a different client, see the client application's documentation for how to connect using certificate-based authentication.

9.9. Setting up SASL Identity Mapping

Red Hat Directory Server supports LDAP client authentication through the Simple Authentication and Security Layer (SASL), an alternative to TLS and a native way for some applications to share information securely.
Simple Authentication and Security Layer (SASL) is an abstraction layer between protocols like LDAP and authentication methods like GSS-API which allows any protocol which can interact with SASL to utilize any authentication mechanism which can work with SASL. Simply put, SASL is an intermediary that makes authenticating to applications using different mechanisms easier. SASL can also be used to establish an encrypted session between a client and server.
The SASL framework allows different mechanisms to be used to authenticate a user to the server, depending on what mechanism is enabled in both client and server applications. SASL also creates a layer for encrypted (secure) sessions. Using GSS-API, Directory Server utilizes Kerberos tickets to authenticate sessions and encrypt data.

9.9.1. About SASL Identity Mapping

When processing a SASL bind request, the server matches, or maps, the SASL authentication ID used to authenticate to the Directory Server with an LDAP entry stored within the server. When using Kerberos, the SASL user ID usually has the format userid@REALM, such as scarter@EXAMPLE.COM. This ID must be converted into the DN of the user's Directory Server entry, such as uid=scarter,ou=people,dc=example,dc=com.
If the authentication ID clearly corresponds to the LDAP entry for a person, it is possible to configure the Directory Server to map the authentication ID automatically to the entry DN. Directory Server has some pre-configured default mappings which handle most common configurations, and customized maps can be created. By default, during a bind attempt, only the first matching mapping rule is applied if SASL mapping fallback is not enabled. For further details about SASL mapping fallback, see Section 9.9.4, “Enabling SASL Mapping Fallback”.
Be sure to configure SASL maps so that only one mapping rule matches the authentication string.
SASL mappings are configured by entries under a container entry:
dn: cn=sasl,cn=config
objectClass: top
objectClass: nsContainer
cn: sasl
SASL identity mapping entries are children of this entry:
dn: cn=mapping,cn=sasl,cn=config
objectClass: top
objectClass: nsContainer
cn: mapping
Mapping entries are defined by the following attributes:
  • nsSaslMapRegexString: The regular expression which is used to map the elements of the supplied authid.
  • nsSaslMapFilterTemplate: A template which applies the elements of the nsSaslMapRegexString to create the DN.
  • nsSaslMapBaseDNTemplate: Provides the search base or a specific entry DN to match against the constructed DN.
  • Optional: nsSaslMapPriority: Sets the priority of this SASL mapping. The priority value is used, if nsslapd-sasl-mapping-fallback is enabled in cn=config. For details, see Section 9.9.4.1, “Setting SASL Mapping Priorities”.
For further details, see the corresponding section in the Red Hat Directory Server Configuration, Command, and File Reference.
For example:
dn: cn=mymap,cn=mapping,cn=sasl,cn=config
objectclass:top
objectclass:nsSaslMapping
cn: mymap
nsSaslMapRegexString: \(.*\)@\(.*\)\.\(.*\)
nsSaslMapFilterTemplate: (objectclass=inetOrgPerson)
nsSaslMapBaseDNTemplate: uid=\1,ou=people,dc=\2,dc=\3
The nsSaslMapRegexString attribute sets variables of the form \1, \2, \3 for bind IDs which are filled into the template attributes during a search. This example sets up a SASL identity mapping for any user in the ou=People,dc=example,dc=com subtree who belongs to the inetOrgPerson object class.
When a Directory Server receives a SASL bind request with mconnors@EXAMPLE.COM as the user ID (authid), the regular expression fills in the base DN template with uid=mconnors,ou=people,dc=EXAMPLE,dc=COM as the user ID, and authentication proceeds from there.

Note

The dc values are not case sensitive, so dc=EXAMPLE and dc=example are equivalent.
The Directory Server can also use a more inclusive mapping scheme, such as the following:
dn: cn=example map,cn=mapping,cn=sasl,cn=config
objectclass: top
objectclass: nsSaslMapping
cn: example map
nsSaslMapRegexString: \(.*\)
nsSaslMapBaseDNTemplate: ou=People,dc=example,dc=com
nsSaslMapFilterTemplate: (cn=\1)
This matches any user ID and map it an entry under the ou=People,dc=example,dc=com subtree which meets the filter cn=userId.
Mappings can be confined to a single realm by specifying the realm in the nsSaslMapRegexString attribute. For example:
dn: cn=example map,cn=mapping,cn=sasl,cn=config
objectclass: top
objectclass: nsSaslMapping
cn: example map
nsSaslMapRegexString: \(.*\)@US.EXAMPLE.COM   
nsSaslMapBaseDNTemplate: ou=People,dc=example,dc=com
nsSaslMapFilterTemplate: (cn=\1)
This mapping is identical to the previous mapping, except that it only applies to users authenticating from the US.EXAMPLE.COM realm. (Realms are described in Section 9.10.2.1, “About Principals and Realms”.)
When a server connects to another server, such as during replication or with chaining, the default mappings for the will not properly map the identities. This is because the principal (SASL identity) for one server does not match the principal on the server where authentication is taking place, so it does not match the mapping entries.
To allow server to server authentication using SASL, create a mapping for the specific server principal to a specific user entry. For example, this mapping matches the ldap1.example.com server to the cn=replication manager,cn=config entry. The mapping entry itself is created on the second server, such as ldap2.example.com.
dn: cn=z,cn=mapping,cn=sasl,cn=config
objectclass: top
objectclass: nsSaslMapping
cn: z
nsSaslMapRegexString: ldap/ldap1.example.com@EXAMPLE.COM
nsSaslMapBaseDNTemplate: cn=replication manager,cn=config
nsSaslMapFilterTemplate: (objectclass=*)
Sometimes, the realm name is not included in the principal name in SASL GSS-API configuration. A second mapping can be created which is identical to the first, only without specifying the realm in the principal name. For example:
dn: cn=y,cn=mapping,cn=sasl,cn=config
objectclass: top
objectclass: nsSaslMapping
cn: y
nsSaslMapRegexString: ldap/ldap1.example.com
nsSaslMapBaseDNTemplate: cn=replication manager,cn=config
nsSaslMapFilterTemplate: (objectclass=*)
Because the realm is not specified, the second mapping is more general (meaning, it has the potential to match more entries than the first. The best practice is to have more specific mappings processed first and gradually progress through more general mappings.
If a priority is not set for a SASL mapping using the nsSaslMapPriority parameter, there is no way to specify the order that mappings are processed. However, there is a way to control how SASL mappings are processed: the name. The Directory Server processes SASL mappings in reverse ASCII order. In the past two example, then the cn=z mapping (the first example) is processed first. If there is no match, the server processes the cn=y mapping (the second example).

Note

SASL mappings can be added when an instance is created during a silent installation by specifying the mappings in an LDIF file and adding the LDIF file with the ConfigFile directive. Using silent installation is described in the Installation Guide.

9.9.2. Default SASL Mappings for Directory Server

The Directory Server has pre-defined SASL mapping rules to handle some of the most common usage.
Kerberos UID Mapping

This matches a Kerberos principal using a two part realm, such as user@example.com. The realm is then used to define the search base, and the user ID (authid) defines the filter. The search base is dc=example,dc=com and the filter of (uid=user).

dn: cn=Kerberos uid mapping,cn=mapping,cn=sasl,cn=config
objectClass: top
objectClass: nsSaslMapping
cn: Kerberos uid mapping
nsSaslMapRegexString: \(.*\)@\(.*\)\.\(.*\)
nsSaslMapBaseDNTemplate: dc=\2,dc=\3
nsSaslMapFilterTemplate: (uid=\1)
RFC 2829 DN Syntax

This mapping matches an authid that is a valid DN (defined in RFC 2829) prefixed by dn:. The authid maps directly to the specified DN.

dn: cn=rfc 2829 dn syntax,cn=mapping,cn=sasl,cn=config
objectClass: top
objectClass: nsSaslMapping
cn: rfc 2829 dn syntax
nsSaslMapRegexString: ^dn:\(.*\)
nsSaslMapBaseDNTemplate: \1
nsSaslMapFilterTemplate: (objectclass=*)
RFC 2829 U Syntax

This mapping matches an authid that is a UID prefixed by u:. The value specified after the prefix defines a filter of (uid=value). The search base is hard-coded to be the suffix of the default userRoot database.

dn: cn=rfc 2829 u syntax,cn=mapping,cn=sasl,cn=config
objectClass: top
objectClass: nsSaslMapping
cn: rfc 2829 u syntax
nsSaslMapRegexString: ^u:\(.*\)
nsSaslMapBaseDNTemplate: dc=example,dc=com
nsSaslMapFilterTemplate: (uid=\1)
UID Mapping

This mapping matches an authid that is any plain string that does not match the other default mapping rules. It use this value to define a filter of (uid=value). The search base is hard-coded to be the suffix of the default userRoot database.

dn: cn=uid mapping,cn=mapping,cn=sasl,cn=config
objectClass: top
objectClass: nsSaslMapping
cn: uid mapping
nsSaslMapRegexString: ^[^:@]+$
nsSaslMapBaseDNTemplate: dc=example,dc=com
nsSaslMapFilterTemplate: (uid=&)

9.9.3. Configuring SASL Identity Mapping

SASL identity mapping can be configured from either the Directory Server or the command line. For SASL identity mapping to work for SASL authentication, the mapping must return one, and only one, entry that matches and Kerberos must be configured on the host machine.

9.9.3.1. Configuring SASL Identity Mapping from the Console

  1. In the Directory Server Console, open the Configuration tab.
  2. Select the SASL Mapping tab.
  3. To add a new SASL identity mapping, select the Add button, and fill in the required values.
    • Name. This field sets the unique name of the SASL mapping.
    • Regular expression. This field sets the regular expression used to match the DN components, such as \(.*\). This field corresponds to the nsSaslMapRegexString value in the SASL mapping LDIF entry.
    • Search base DN. This field gives the base DN to search to map entries, such as ou=People,dc=example,dc=com. This field corresponds to the nsSaslMapBaseDNTemplate value in the SASL mapping LDIF entry.
    • Search filter. This field gives the search filter for the components to replace, such as (objectclass=*). This field corresponds to the nsSaslMapFilterTemplate value in the SASL mapping LDIF entry.
To edit a SASL identity mapping, highlight that identity in the SASL Mapping tab, and click Modify. Change any values, and save.
To delete a SASL identity mapping, highlight it and hit Delete. A dialog box comes up to confirm the deletion.

9.9.3.2. Configuring SASL Identity Mapping from the Command Line

To configure SASL identity mapping from the command line, use the ldapmodify utility to add the identity mapping scheme. For example:
# ldapmodify -a -D "cn=Directory Manager" -W -p 389 -h server.example.com -x 

dn: cn=example map,cn=mapping,cn=sasl,cn=config
changetype: add
objectclass: top
objectclass: nsSaslMapping
cn: example map
nsSaslMapRegexString: \(.*\)
nsSaslMapBaseDNTemplate: ou=People,dc=example,dc=com
nsSaslMapFilterTemplate: (cn=\1)
This matches any user's common name and maps it to the result of the subtree search with base ou=People,dc=example,dc=com, based on the filter cn=userId.

Note

When SASL maps are added over LDAP, they are not used by the server until it is restarted. Adding the SASL map with ldapmodify adds the mapping to the end of the list, regardless of its ASCII order.

9.9.4. Enabling SASL Mapping Fallback

Using the default settings, Directory Server verifies only the first matching SASL mapping. If this first matching mapping fails, the bind operation fails and no further matching mappings are verified.
However, you can configure Directory Server to verify all matching mappings by enabling the nsslapd-sasl-mapping-fallback parameter:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: cn=config
changetype: modify
replace: nsslapd-sasl-mapping-fallback
nsslapd-sasl-mapping-fallback: on
If fallback is enabled and only one user identity is returned, the bind succeeds. If no user, or more than one user is returned, the bind fails.

9.9.4.1. Setting SASL Mapping Priorities

If you enabled SASL mapping fallback using the nsslapd-sasl-mapping-fallback attribute, you can optionally set the nsSaslMapPriority attribute in mapping configurations to prioritize them. The nsSaslMapPriority attribute supports values from 1 (highest priority) to 100 (lowest priority). The default is 100.
For example, to set the highest priority for the cn=Kerberos uid mapping,cn=mapping,cn=sasl,cn=config mapping:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: cn=Kerberos uid mapping,cn=mapping,cn=sasl,cn=config
changetype: modify
replace: nsSaslMapPriority
nsSaslMapPriority: 1

9.10. Using Kerberos GSS-API with SASL

Kerberos v5 must be deployed on the host for Directory Server to utilize the GSS-API mechanism for SASL authentication. GSS-API and Kerberos client libraries must be installed on the Directory Server host to take advantage of Kerberos services.

9.10.1. Authentication Mechanisms for SASL in Directory Server

Directory Server support the following SASL encryption mechanisms:
  • PLAIN. PLAIN sends cleartext passwords for simple password-based authentication.
  • EXTERNAL. EXTERNAL, as with TLS, performs certificate-based authentication. This method uses public keys for strong authentication.
  • CRAM-MD5. CRAM-MD5 is a weak, simple challenge-response authentication method. It does not establish any security layer.

    Warning

    Red Hat recommends not using the insecure CRAM-MD5 mechanism.
  • DIGEST-MD5. DIGEST-MD5 is a weak authentication method for LDAPv3 servers.

    Warning

    Red Hat recommends not using the insecure DIGGEST-MD5 mechanism.
  • Generic Security Services (GSS-API). Generic Security Services (GSS) is a security API that is the native way for UNIX-based operating systems to access and authenticate Kerberos services. GSS-API also supports session encryption, similar to TLS. This allows LDAP clients to authenticate with the server using Kerberos version 5 credentials (tickets) and to use network session encryption.
    For Directory Server to use GSS-API, Kerberos must be configured on the host machine. See Section 9.10, “Using Kerberos GSS-API with SASL”.

    Note

    GSS-API and, thus, Kerberos are only supported on platforms that have GSS-API support. To use GSS-API, it may be necessary to install the Kerberos client libraries; any required Kerberos libraries will be available through the operating system vendor.

9.10.2. About Kerberos in Directory Server

On Red Hat Enterprise Linux, the supported Kerberos libraries are MIT Kerberos version 5.
The concepts of Kerberos, as well as using and configuring Kerberos, are covered at the MIT Kerberos website, http://web.mit.edu/Kerberos/.

9.10.2.1. About Principals and Realms

A principal is a user or service in the Kerberos environment. A realm defines what Kerberos manages in terms of who can access what. The client, the KDC, and the host or service you want to access must use the same realm.

Note

Kerberos realms are only supported for GSS-API authentication and encryption, not for DIGEST-MD5.
Realms are used by the server to associate the DN of the client in the following form, which looks like an LDAP DN:
uid=user_name/[server_instance],cn=realm,cn=mechanism,cn=auth
For example, Mike Connors in the engineering realm of the European division of example.com uses the following association to access a server in the US realm:
uid=mconnors/cn=Europe.example.com,cn=engineering,cn=gssapi,cn=auth
Babara Jensen, from the accounting realm of US.example.com, does not have to specify a realm when to access a local server:
uid=bjensen,cn=accounting,cn=gssapi,cn=auth
If realms are supported by the mechanism and the default realm is not used to authenticate to the server, then the realm must be specified in the Kerberos principal. Otherwise, the realm can be omitted.

Note

Kerberos systems treat the Kerberos realm as the default realm; other systems default to the server.

9.10.2.2. About the KDC Server and Keytabs

The Key Distribution Center (KDC) authenticates users and issues Ticket Granting Tickets (TGT) for them. This enables users to authenticate to Directory Server using GSS-API. To respond to Kerberos operations, Directory Server requires access to its keytab file. The keytab contains the cryptographic key that Directory Server uses to authenticate to other servers.
Directory Server uses the ldap service name in a Kerberos principal. For example:
ldap/server.example.com/EXAMPLE.COM
For details about creating the keytab, see your Kerberos documentation.

Note

You must create a Simple Authentication and Security Layer (SASL) mapping for the Directory Server Kerberos principal that maps to an existing entry Distinguished Name (DN).

9.10.3. Configuring SASL Authentication at Directory Server Startup

SASL GSS-API authentication has to be activated in Directory Server so that Kerberos tickets can be used for authentication. This is done by supplying a system configuration file for the init scripts to use which identifies the variable to set the keytab file location. When the init script runs at Directory Server startup, SASL authentication is then immediately active.
The default SASL configuration is stored in the /etc/sysconfig/dirsrv file.
If there are multiple Directory Server instances and not all of them will use SASL authentication, then there can be instance-specific configuration files created in the /etc/sysconfig/ directory named dirsrv-instance. For example, dirsrv-example. The default dirsrv file can be used if there is a single instance on a host.
To enable SASL authentication, uncomment the KRB5_KTNAME line in the /etc/sysconfig/dirsrv (or instance-specific) file, and set the keytab location for the KRB5_KTNAME variable. For example:
# In order to use SASL/GSSAPI the directory
# server needs to know where to find its keytab
# file - uncomment the following line and set
# the path and filename appropriately
KRB5_KTNAME=/etc/dirsrv/krb5.keytab

9.11. Setting SASL Mechanisms

Per default, Directory Server enables all mechanisms the simple authentication and security layer (SASL) library supports. These are listed in the root dse supportedSASLMechanisms parameter. To enable specific SASL mechanisms, set the nsslapd-allowed-sasl-mechanisms attribute in the cn=config entry. For example, to enable only the GSSAPI and DIGEST-MD5 mechanism, run:
# ldapmodify -D "cn=Directory Manager" -W -x

dn: cn=config
changetype: modify
replace: nsslapd-allowed-sasl-mechanisms
nsslapd-allowed-sasl-mechanisms: GSSAPI, DIGEST-MD5

Note

Even if EXTERNAL is not listed in the nsslapd-allowed-sasl-mechanisms attribute, this mechanism is always enabled.
For further details, see the corresponding section in the Red Hat Directory Server Configuration, Command, and File Reference.

9.12. Using SASL with LDAP Clients

To use SASL with the LDAP clients, such as ldapsearch, pass the -Y SASL_mechanism to the command. For example:
  • To use the GSSAPI SASL mechanism over the LDAP protocol:
    # ldapsearch -Y GSSAPI -U "dn:uid=user_name,ou=people,dc=example,dc=com" -R EXAMPLE.COM -H ldap://server.example.com -b "dc=example,dc=com"
  • To use the PLAIN SASL mechanism over the LDAPS protocol:
    # ldapsearch -Y PLAIN -D "uid=user_name,ou=people,dc=example,dc=com" -W -H ldaps://server.example.com -b "dc=example,dc=com"

Note

SASL proxy authorization is not supported in Directory Server. Therefore, Directory Server ignores any SASL authzid value supplied by the client.

Chapter 10. Configuring Attribute Encryption

The Directory Server offers a number of mechanisms to secure access to sensitive data, such as access control rules to prevent unauthorized users from reading certain entries or attributes within entries and TLS to protect data from eavesdropping and tampering on untrusted networks. However, if a copy of the server's database files should fall into the hands of an unauthorized person, they could potentially extract sensitive information from those files. Because information in a database is stored in plain text, some sensitive information, such as government identification numbers or passwords, may not be protected enough by standard access control measures.
For highly sensitive information, this potential for information loss could present a significant security risk. In order to remove that security risk, Directory Server allows portions of its database to be encrypted. Once encrypted, the data are safe even in the event that an attacker has a copy of the server's database files.
Database encryption allows attributes to be encrypted in the database. Both encryption and the encryption cipher are configurable per attribute per back end. When configured, every instance of a particular attribute, even index data, is encrypted for every entry stored in that database.
An additional benefit of attribute encryption is, that encrypted values can only be sent to a clients with a Security Strength Factor (SSF) greater than 1.

Note

There is one exception to encrypted data: any value which is used as the RDN for an entry is not encrypted within the entry DN. For example, if the uid attribute is encrypted, the value is encrypted in the entry but is displayed in the DN:
# entry-id: 16
dn: uid=jsmith1234,ou=People,dc=example,dc=com
nsUniqueId: ee91ea82-1dd111b2-9f36e9bc-39fb8550
objectClass: top
objectClass: person
objectClass: organizationalPerson
objectClass: inetorgperson
givenName: John
sn: Smith
uid:: Sf04P9nJWGU1qiW9JJCGRg==
That would allow someone to discover the encrypted value.
Any attribute used within the entry DN cannot be effectively encrypted, since it will always be displayed in the DN. Be aware of what attributes are used to build the DN and design the attribute encryption model accordingly.
Indexed attributes may be encrypted, and attribute encryption is fully compatible with eq and pres indexing. The contents of the index files that are normally derived from attribute values are also encrypted to prevent an attacker from recovering part or all of the encrypted data from an analysis of the indexes.
Since the server pre-encrypts all index keys before looking up an index for an encrypted attribute, there is some effect on server performance for searches that make use of an encrypted index, but the effect is not serious enough that it is no longer worthwhile to use an index.

10.1. Encryption Keys

In order to use attribute encryption, the server must be configured for TLS and have TLS enabled because attribute encryption uses the server's TLS encryption key and the same PIN input methods as TLS. The PIN must either be entered manually upon server startup or a PIN file must be used.
Randomly generated symmetric cipher keys are used to encrypt and decrypt attribute data. A separate key is used for each configured cipher. These keys are wrapped using the public key from the server's TLS certificate, and the resulting wrapped key is stored within the server's configuration files. The effective strength of the attribute encryption is never higher than the strength of the server's TLS key used for wrapping. Without access to the server's private key, it is not possible to recover the symmetric keys from the wrapped copies.

Warning

There is no mechanism for recovering a lost key. Therefore, it is especially important to back up the server's certificate database safely. If the server's certificate were lost, it would not be possible to decrypt any encrypted data stored in its database.

Warning

If the TLS certificate is expiring and needs to be renewed, export the encrypted back end instance before the renewal. Update the certificate, then re-import the exported LDIF file.

10.2. Encryption Ciphers

The encryption cipher is configurable on a per-attribute basis and must be selected by the administrator at the time encryption is enabled for an attribute. Configuration can be done through the Console or through the command line.
The following ciphers are supported:
  • Advanced Encryption Standard (AES)
  • Triple Data Encryption Standard (3DES)

Note

For strong encryption, Red Hat recommends using only AES ciphers.
All ciphers are used in Cipher Block Chaining mode.
Once the encryption cipher is set, it should not be changed without exporting and re-importing the data.

10.3. Configuring Attribute Encryption from the Console

  1. In the Configuration tab, select the Data node.
  2. Expand the suffix, and select the database to edit.
  3. Select the Attribute Encryption tab.
  4. Click the Add Attribute button to open the list of attributes. Select the attribute to encrypt.

    Note

    For existing attribute values to be encrypted, the information must be exported from the database, then re-imported. See Section 10.7, “Exporting and Importing an Encrypted Database”.
  5. Select which encryption cipher to use.

Note

The encryption cipher to use is set separately for each attribute, so attribute encryption is applied to each attribute one at a time.
To remove encryption from attributes, select them from the list of encrypted attributes in the Attribute Encryption table, click the Delete button, and then click Save to apply the changes. Any deleted attributes have to be manually re-added after saving.

10.4. Configuring Attribute Encryption Using the Command Line

  1. Run the ldapmodify command:
    # ldapmodify -a -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
  2. Add an encryption entry for the attribute being encrypted. For example, this entry encrypts the telephoneNumber attribute with the AES cipher:
    dn: cn=telephoneNumber,cn=encrypted attributes,cn=Database1,cn=ldbm database,cn=plugins,cn=config
    changetype: add
    objectclass: top
    objectclass: nsAttributeEncryption
    cn: telephoneNumber
    nsEncryptionAlgorithm: AES
  3. For existing attributes in entries to be encrypted, the information must be exported, then re-imported. See Section 10.7, “Exporting and Importing an Encrypted Database”.
For more information on attribute encryption configuration schema, see "Database Attributes under cn=attributeName,cn=encrypted attributes,cn=database_name,cn=ldbm database,cn=plugins,cn=config" in the Red Hat Directory Server Configuration, Command, and File Reference.

10.5. Enabling Attribute Encryption for Existing Attribute Values

To enable attribute encryption on an attribute with existing stored data, export the database to LDIF first, then make the configuration change, then re-import the data to the database. The server does not enforce consistency between encryption configuration and stored data; therefore, pay careful attention that all existing data are exported before enabling or disabling encryption.

10.6. General Considerations after Enabling Attribute Encryption

When you enable encryption for data that is already in the database:
  • Unencrypted data can persist in the server's database page pool backing file. To remove this data:
    1. Stop the instance:
      # systemctl stop dirsrv@instance_name
    2. Delete the /var/lib/dirsrv/slapd-instance_name/db/guardian file:
      # rm /var/lib/dirsrv/slapd-instance_name/db/guardian
    3. Start the instance:
      # systemctl start dirsrv@instance_name
  • After you enabled encryption and successfully imported the data, delete the LDIF file with the unencrypted data.
  • After enabling encryption, the Directory Server deletes and creates a new database when re-importing the data.
  • The replication log file is not encrypted. To protect this data, store it on an encrypted disk.
  • Data in the server's memory (RAM) is unencrypted and can be temporarily stored in swap partitions. To protect this data, set up encrypted swap space.

Important

Even if you delete files that contain unencrypted data, this data can be restored under certain circumstances.

10.7. Exporting and Importing an Encrypted Database

Exporting and importing encrypted databases is similar to exporting and importing regular databases. However, the encrypted information must be decrypted when you export the data and re-encrypted when you re-import it to the database.

10.7.1. Exporting an Encrypted Database

To export data from an encrypted database, pass the -E parameter to the db2ldif script. The script uses the password stored in the Directory Sever configuration to decrypt the database.
To encrypt a complete database:
# db2ldif -Z instance_name -n database_name -E -a /tmp/data.ldif
Alternatively, you can export only a specific subtree. For example, to export all data from the ou=People,dc=example,dc=com entry into the /tmp/export.ldif file:
# db2ldif -Z instance_name -n database_name -E -s "ou=people,dc=example,dc=com" \
     -a /tmp/data.ldif

Important

The db2ldif script exports the content using the operating system account of the Directory Server instance. Therefore, this account must be able to write to the file set in the -a option.

10.7.2. Importing an LDIF File into an Encrypted Database

To import data to a database when encryption is enabled:
  1. Stop the Directory Server instance:
    # systemctl stop dirsrv@instance_name
  2. If you replaced the certificate database between the last export and this import, edit the /etc/dirsrv/slapd-instance_name/dse.ldif file and remove the following entries including their attributes:
    • cn=AES,cn=encrypted attribute keys,cn=database_name,cn=ldbm database,cn=plugins,cn=config
    • cn=3DES,cn=encrypted attribute keys,cn=database_name,cn=ldbm database,cn=plugins,cn=config

    Important

    Remove the entries for all databases. If any entry that contains the nsSymmetricKey attribute is left in the /etc/dirsrv/slapd-instance_name/dse.ldif file, Directory Server will fail to start.
  3. Import the LDIF file. For example:
    # ldif2db -Z instance_name -n database_name -E -i /tmp/data.ldif
    The -E parameter enables the script to encrypt attributes configure for encryption during the import.
  4. Start the instance:
    # systemctl start dirsrv@instance_name

10.8. Updating the TLS Certificates Used for Attribute Encryption

Attribute encryption is based on the TLS certificate. To prevent that attribute encryption fails after renewing or replacing the TLS certificate:
  1. Export the database with decrypted attributes. See Section 10.7.1, “Exporting an Encrypted Database”.
  2. Delete the existing private key and certificate from the Network Security Services (NSS) database. See Section 9.3.8, “Removing a Private Key”
  3. Create a new Certificate Signing Request (CSR). See Section 9.3.2, “Creating a Certificate Signing Request”.
  4. Install the new certificate. See Section 9.3.4, “Installing a Certificate”.
  5. Stop the Directory Server instance:
    # systemctl stop dirsrv@instance_name
  6. Edit the /etc/dirsrv/slapd-instance_name/dse.ldif file and remove the following entries including their attributes:
    • cn=AES,cn=encrypted attribute keys,cn=database_name,cn=ldbm database,cn=plugins,cn=config
    • cn=3DES,cn=encrypted attribute keys,cn=database_name,cn=ldbm database,cn=plugins,cn=config

    Important

    Remove the entries for all databases. If any entry that contains the nsSymmetricKey attribute is left in the /etc/dirsrv/slapd-instance_name/dse.ldif file, Directory Server will fail to start.
  7. Start the instance:
    # systemctl start dirsrv@instance_name

Chapter 11. Managing FIPS Mode Support

Red Hat Directory Server fully supports the Federal Information Processing Standard (FIPS) 140-2. When Directory Server runs in FIPS mode, security-related settings change. For example, SSL is automatically disabled and only TLS 1.1 and 1.2 encryption is used.
For general details about FIPS, see Federal Information Processing Standard (FIPS) in the Red Hat Enterprise Linux Security Guide.

Enabling FIPS Mode Support

To enable FIPS mode support for Directory Server:
  1. Optionally, enable FIPS mode in Red Hat Enterprise Linux. For details, see the corresponding section in the Red Hat Enterprise Linux Security Guide.
  2. Enable FIPS mode for the network security services (NSS) database:
    # modutil -dbdir /etc/dirsrv/slapd-instance_name/ -fips true
  3. Restart the Directory Server instance:
    # systemctl restart dirsrv@instance_name

Disabling FIPS Mode Support

To disable FIPS mode support for Directory Server:
  1. Disable FIPS mode for the network security services (NSS) database:
    # modutil -dbdir /etc/dirsrv/slapd-instance_name/ -fips false
  2. Restart the Directory Server instance:
    # systemctl restart dirsrv@instance_name
  3. Optionally, disable FIPS mode in Red Hat Enterprise Linux. For details, see the corresponding section in the Red Hat Enterprise Linux Security Guide.

Chapter 12. Managing the Directory Schema

Red Hat Directory Server comes with a standard schema that includes hundreds of object classes and attributes. While the standard object classes and attributes should meet most deployments' requirements, it can be necessary to extend the schema for specific directory data. Extending the schema is done by creating new object classes and attributes.
The Red Hat Directory Server 10 Configuration, Command, and File Reference is a reference for most the standard Directory Server attributes and object classes, with information on allowed and required attributes, which object classes take which attribute, and OID and value information. This is a good resource for identifying useful schema elements for a directory and determining what custom schema needs to be created.

12.1. Overview of Schema

The directory schema is a set of rules that defines how data can be stored in the directory. Directory information is stored discrete entries, and each entry is comprised of a set of attributes and their values. The kind of identity being described in the entry is defined in the entry's object classes. An object class specifies the kind of object the entry describes through the defined set of attributes for the object class.
In LDAP, an object class defines the set of attributes that can be used to define an entry. The LDAP standard provides object classes for many common types of entries, including people, groups, locations, organizations and divisions, and equipment. The identity is described in a directory entries with attributes and their values, pairs are called attribute-value assertions or AVAs. Any piece of information in the directory is associated with a descriptive attribute. Other aspects of the Directory Server configuration, including matching rules and LDAP controls, are also defined in the schema. All of these together are schema elements.
Every schema element is identified by a unique, dot-separated number. This is called the object identifier or OID.

12.1.1. Default Schema Files

The schema for Directory Server is defined in several different schema files (LDIF files which define schema elements). The Directory Server schema files are located in the /usr/share/dirsrv/schema/ directory. The files in this directory are used as templates for new Directory Server instances. Adding a new schema into this directory will make it available to any new instances.
The attributes used by the Directory Server to perform operations and manage entries is described with other configuration settings in the Red Hat Directory Server 10 Configuration, Command, and File Reference.

12.1.2. Object Classes

In LDAP, an object class defines the set of attributes that can be used to define an entry. The LDAP standard provides object classes for many common types of entries, such as people (person and inetOrgPerson), groups (groupOfNames), locations (locality), organizations and divisions (organization and organizationalUnit), and equipment (device).
In a schema file, an object class is identified by the objectclasses line, then followed by its OID, name, a description, its direct superior object class (an object class which is required to be used in conjunction with the object class and which shares its attributes with this object class), and the list of required (MUST) and allowed (MAY) attributes.

Example 12.1. person Object Class Schema Entry

objectClasses: ( 2.5.6.6 NAME 'person' DESC 'Standard LDAP objectclass' SUP top MUST ( sn $ cn ) MAY ( description $ seeAlso $ telephoneNumber $ userPassword ) X-ORIGIN 'RFC 4519' )
Every object class defines a number of required attributes (MUST keyword in the schema) and of allowed attributes (MAY keyword in the schema). Required attributes must be present in entries using the specified object class, while allowed attributes are permissible and available for the entry to use, but are not required for the entry to be valid.
As in Example 12.1, “person Object Class Schema Entry”, the person object class requires the cn, sn, and objectClass attributes and allows the description, seeAlso, telephoneNumber, and userPassword attributes.
An object class can inherit attributes from another class, in addition to its own required and allowed attributes. The second object class is the superior or parent object class of the first.
For example, a user's entry has to have the inetOrgPerson object class. In that case, the entry must also include the superior object class for inetOrgPerson, organizationalPerson, and the superior object class for organizationalPerson, which is person:
objectClass: top
objectClass: person
objectClass: organizationalPerson
objectClass: inetOrgPerson

12.1.3. Attributes

Directory entries are composed of attributes and their values. These pairs are called attribute-value assertions or AVAs. Any piece of information in the directory is associated with a descriptive attribute. For instance, the cn attribute is used to store a person's full name, such as cn: John Smith.
Additional attributes can supply additional information about John Smith:
givenname: John
surname: Smith
mail: jsmith@example.com
In a schema file, an attribute is described by:
  • OID
  • name
  • syntax matching rule (optional)
  • substring matching rules (optional)
  • ordering rule (optional)
  • description (optional)
  • syntax
  • single-valued or multi-valued attribute
  • details about where the attribute is defined

Example 12.2. uid Attribute Schema Entry

( 0.9.2342.19200300.100.1.1 NAME ( 'uid' 'userid' ) EQUALITY caseIgnoreMatch SUBSTR caseIgnoreSubstringsMatch SYNTAX 1.3.6.1.4.1.1466.115.121.1.15 X-ORIGIN 'RFC 4519' )

12.1.4. Extending the Schema

New, custom attributes and object classes can be added to a Directory Server instance to extend the schema, and there are several ways to add schema elements. Using the Directory Server Console or LDAP tools adds schema elements to the default custom schema file for an instance, 99user.ldif. It is also possible to create a new, separate schema file and include it with the default schema files.
Adding new schema elements requires three things:
  1. Planning and defining OIDs for the new schema. Schema elements are recognized by the server by their OID, so it is important for the OIDs to be unique and organized. Directory Server itself does not manage OIDs, but there are some best practices described in Section 12.2, “Managing Object Identifiers”.
  2. Create the new attributes. Attribute definitions require a name, a syntax (the allowed format of the values), an OID, and a description of whether the attribute can only be used once per entry or multiple times.
  3. Create an object class to contain the new attributes. An object class lists the required attributes for that entry type and the allowed (permissible) attributes. Because the default schema should never be altered, if any new attributes are created, then they should be added to a custom object class.
The schema elements should be planned in advance; do not use multiple attributes for the same information. Whenever possible, use the standard Directory Server schema. Directory Server has hundreds of attributes and dozens of object classes defined in the default schema files. The Red Hat Directory Server 10 Configuration, Command, and File Reference lists and describes the standard attributes and object classes; all of the schema can be viewed in the Directory Server Console or read in the schema files in /usr/share/dirsrv/schema/. Become familiar with the available schema; then plan what information attributes are missing and how best to fill those gaps with custom attributes. Planning the schema is covered in the Deployment Guide.

Warning

The default object classes and attributes in Directory Server are based on LDAP and X.500 standards and RFCs. Using standard schema makes the Directory Server more easily integrated with other applications and servers and allows interoperability with LDAP clients, legacy Directory Server instances, and future release. It is inadvisable for you to edit the standard attributes or change the object classes.
Keep the following rules in mind when customizing the Directory Server schema:
  • Keep the schema as simple as possible.
  • Reuse existing schema elements whenever possible.
  • Minimize the number of mandatory attributes defined for each object class.
  • Do not define more than one object class or attribute for the same purpose.
  • Do not modify any existing definitions of attributes or object classes.

Note

Never delete or replace the standard schema. Doing so can lead to compatibility problems with other directories or other LDAP client applications.
The schema is loaded into the Directory Server instance when the instance is started; any new schema files are not loaded until the Directory Server is restarted or unless a reload task is initiated. The default custom schema file for an instance, 99user.ldif, is loaded as the last schema file. If it contains definitions already present in standard schema files, the custom definition will override the standard ones.

12.1.5. Schema Replication

When the directory schema is updated in the cn=schema sub-tree, Directory Server stores the changes in the local /etc/dirsrv/slapd-instance_name/schema/99user.ldif file, including a change state number (CSN). The updated schema is not automatically replicated to other replicas. The schema replication starts when directory content is updated in the replicated tree. For example, if you update a user or group entry after modifying the schema, the supplier compares the CSN stored in the nsSchemaCSN attribute with the one on the consumer. If the remote CSN is lower than the one on the supplier, the schema is replicated to the consumer. For a successful replication, all object classes and attribute types on the supplier must be a superset of the consumer's definition.

Example 12.3. Schema subsets and supersets

  • On server1, the demo object class allows the a1, a2, and a3 attributes.
  • On server2, the demo object class allows the a1 and a3 attributes.
In Example 12.3, “Schema subsets and supersets”, the schema definition of the demo object class on server1 is a superset of the object class on server2. During the validation phase, when the schema is being replicated or accepted, Directory Server retrieves the superset definitions. For example, if a consumer detects that an object class in the local schema allows less attributes than the object class in the supplier schema, the local schema is updated.
If the schema definitions are successfully replicated, the nsSchemaCSN attributes are identical on both servers and no longer compared at the beginning of a replication session.
In the following scenarios, the schema is not replicated:
  • The schema on one host is a subset of the schema of another host.
    For example, in Example 12.3, “Schema subsets and supersets”, the schema definition of the demo object class on server2 is a subset of the object class on server1. Subsets can also occur for attributes (a single-value attribute is a subset of a multi-value attribute) and attribute syntaxes (IA5 is a subset of Octet_string).
  • When definitions in supplier schema and consumer schema need to be merged.
    Directory Server does not support merging schemas. For example, if an object class on one server allows the a1, a2, and a3 attributes and a1, a3, and a4 on the other, the schemas are not subsets and cannot be merged.
  • Schema files other than /etc/dirsrv/slapd-instance_name/schema/99user.ldif are used.
    Directory Server enables you to add additional schema files in the /etc/dirsrv/slapd-instance_name/schema/ directory. However, only the CSN in the 99user.ldif file is updated. For this reasons, other schema file are only used locally and are not automatically transferred to replication partners. Copy the updated schema file manually to the consumers and reload the schema. For details, see Section 12.7, “Dynamically Reloading Schema”.
    To avoid duplicate schema definitions and to enable automatic replication, store all custom schema in the /etc/dirsrv/slapd-instance_name/schema/99user.ldif file. For further information about creating custom schema files, see Section 12.6, “Creating Custom Schema Files”.

12.2. Managing Object Identifiers

Each LDAP object class or attribute must be assigned a unique name and object identifier (OID). An OID is a dot-separated number which identifies the schema element to the server. OIDs can be hierarchical, with a base OID that can be expanded to accommodate different branches. For example, the base OID could be 1, and there can be a branch for attributes at 1.1 and for object classes at 1.2.

Note

It is not required to have a numeric OID for creating custom schema, but Red Hat strongly recommends it for better forward compatibility and performance.
OIDs are assigned to an organization through the Internet Assigned Numbers Authority (IANA), and Directory Server does not provide a mechanism to obtain OIDs. To get information about obtaining OIDs, visit the IANA website at http://www.iana.org/cgi-bin/enterprise.pl.
After obtaining a base OID from IANA, plan how the OIDs are going to be assigned to custom schema elements. Define a branch for both attributes and object classes; there can also be branches for matching rules and LDAP controls.
Once the OID branches are defined, create an OID registry to track OID assignments. An OID registry is a list that gives the OIDs and descriptions of the OIDs used in the directory schema. This ensures that no OID is ever used for more than one purpose. Publish the OID registry with the custom schema.

12.3. Directory Server Attribute Syntaxes

The attribute's syntax defines the format of the values which the attribute allows; as with other schema elements, the syntax is defined for an attribute using the syntax's OID in the schema file entry. In the Directory Server Console, the syntax is referenced by its friendly name.
The Directory Server uses the attribute's syntax to perform sorting and pattern matching on entries.
For more information about LDAP attribute syntaxes, see RFC 4517.
Supported LDAP attribute syntaxes are covered in section Directory Server Attribute Syntaxes of the Red Hat Directory Server 10 Configuration, Command, and File Reference.

12.4. Managing Custom Schema in the Console

The Directory Server Console shows all attributes in the schema, and custom attributes can be created, edited, and deleted from the schema.

12.4.1. Viewing Attributes and Object Classes

All of the information about the attributes and object classes which are currently loaded in the server instance are visible with the other server configuration.
  1. In the Directory Server Console, select the Configuration tab.
  2. In the left navigation tree, select the Schema folder.
  3. There are three tabs which display the schema elements loaded in Directory Server: Object Class, Attributes, and Matching Rules.
The Attributes tab is broken into two sections for default and custom attributes. Both sections show the attribute name, OID, syntax, and whether the attribute is multi-valued.
The Object Classes tab shows the list of object classes on the left. When an object class is highlighted, its OID and superior object class are listed in the fields at the top and its required and allowed attributes are listed in the boxes on the right.

12.4.2. Creating Attributes

Note

After adding new attributes to the schema, create a new object class to contain them, as described in Section 12.4.3, “Creating Object Classes”.
  1. Select the Configuration tab.
  2. In the left navigation tree, select the Schema folder, and then select the Attributes tab in the right pane.
  3. Click Create.
  4. Fill in the information for the new attribute.
    • The attribute name; this must be unique.
    • The OID; this is not required, but for compatibility and server performance, assigning a unique numeric OID is strongly recommended.
    • The syntax; this is the allowed format for the attributes values.
    • Whether the attribute is multi-valued; by default, all attributes can be used more than once in an entry, but deselecting the check box means the attribute can be used only once.
  5. Click OK.

12.4.3. Creating Object Classes

A new object class must be created with a unique name, a parent object, and required and optional attributes. To create an object class:
  1. In the Directory Server Console, select the Configuration tab.
  2. In the navigation tree, select the Schema folder, and then select the Object Classes tab in the right pane.
  3. Click the Create button in the Object Classes tab.
  4. Fill in the information about the new object class.
    • The name; this must be unique.
    • The OID; this is not required, but for compatibility and server performance, assigning a unique numeric OID is strongly recommended.
    • The superior object class for the entry. The default is top; selecting another object class means that the new object class inherits all of the required and allowed attributes from the parent, in addition to its own defined attributes.
    • Required and allowed attributes. Select the attributes on the left and used the Add buttons by the Available Attributes and Required Attributes boxes to add the attributes as appropriate.

    Note

    Attributes that are inherited from the parent object classes cannot be removed, regardless of whether they are allowed or required.
  5. Click OK to save the new object class.

12.4.4. Editing Custom Schema Elements

Only user-created attributes or object classes can be edited; standard schema elements cannot be edited.
  1. In the Directory Server Console, select the Configuration tab.
  2. In the left navigation tree, select the Schema folder.
  3. Open the Object Classes or Attributes tab.
  4. Select the schema element to edit from the list. Only custom (user-defined) schema can be edited in the Directory Server Console.
  5. Click the Edit button at the bottom of the window.
  6. Edit any of the schema information.

12.4.5. Deleting Schema

Only user-created attributes or object classes can be deleted; standard schema elements cannot be deleted.
  1. In the Directory Server Console, select the Configuration tab.
  2. In the left navigation tree, select the Schema folder.
  3. Open the Object Classes or Attributes tab.
  4. Select the schema element to delete from the list. Only custom (user-defined) schema can be deleted in the Directory Server Console.
  5. Click the Delete button at the bottom of the window.
  6. Confirm the deletion.

Warning

The server immediately deletes the schema element. There is no undo.

12.5. Managing Schema Using ldapmodify

As with the Directory Server Console, ldapmodify can be used to add, edit, and delete custom schema elements. ldapmodify also modifies the default custom schema file for a Directory Server instance, 99user.ldif.

12.5.1. Creating Attributes

A custom attribute entry is itself an attributetypes entry for the cn=schema entry. The attributetypes attribute has the format:
attributetypes: ( definition )
The definition contains five components:
  • An OID, usually a dot-separated number
  • A unique name, in the form NAME name
  • A description, in the form DESC description
  • The OID for the syntax of the attribute values, discussed in Section 12.3, “Directory Server Attribute Syntaxes”, in the form SYNTAX OID
  • Optionally, the source where the attribute is defined
The attribute definition is added to the custom schema file, 99user.ldif, by running an LDAP command and modifying the cn=schema entry. For example:
# ldapmodify -D "cn=Directory Manager" -W -x -v

dn: cn=schema
changetype: modify
add: attributetypes
attributetypes: ( 1.2.3.4.5.6.1 NAME 'dateofbirth' DESC 'For employee birthdays' SYNTAX 1.3.6.1.4.1.1466.115.121.1.15 SINGLE-VALUED X-ORIGIN 'Example defined')

12.5.2. Creating Object Classes

An object class definition is an objectclasses attribute for the cn=schema entry. The objectclasses attribute has the format:
objectclasses: ( definition )
The object class definition contains several components:
  • An OID, usually a dot-separated number
  • A unique name, in the form NAME name
  • A description, in the form DESC description
  • The superior, or parent, object class for this object class, in the form SUP object_class; if there is no related parent, use SUP top
  • The word AUXILIARY, which gives the type of entry to which the object class applies; AUXILIARY means it can apply to any entry
  • A list of required attributes, preceded by the word MUST; to include multiple attributes, enclose the group in parentheses and separate with attributes with dollar signs ($)
  • A list of allowed attributes, preceded by the word MAY; to include multiple attributes, enclose the group in parentheses and separate with attributes with dollar signs ($)
The object class definition is added to the custom schema file, 99user.ldif, by by running an LDAP command and modifying the cn=schema entry. For example:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x -v

dn: cn=schema
changetype: modify
add: objectclasses
objectclasses: ( 2.16.840.1133730.2.123 NAME 'examplePerson' DESC 'Example Person Object Class' SUP inetOrgPerson AUXILIARY  MUST cn MAY (exampleDateOfBirth $ examplePreferredOS) )

12.5.3. Deleting Schema

Warning

Never delete default schema elements. Those are required by the Directory Server to run.
  1. Remove the unwanted attributes from any entries which use them, then from any object classes in the schema file which accept that attribute. Likewise, to remove an object class, remove it from any entries.
  2. Run ldapmodify to remove the attribute. For example:
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn: cn=schema
    changetype: modify
    delete: objectclasses
    objectclasses: ( 2.16.840.1133730.2.123 NAME 'examplePerson' DESC 'Example Person Object Class' SUP inetOrgPerson AUXILIARY MUST cn MAY (exampleDateOfBirth $ examplePreferredOS) )

    Warning

    Be sure to specify the exact object class or attribute to remove; using only the attributetypes or objectclasses attribute without the value will delete every user-defined attribute or object class in the file.
If the custom attribute or object class is in a custom schema file other than 99user.ldif, edit the file directly. Neither the Directory Server Console nor LDAP tools can edit a schema file other than 99user.ldif.

12.6. Creating Custom Schema Files

Schema files are simple LDIF files which define the cn=schema entry. Each attribute and object class is added as an attribute to that entry. Here are the requirements for creating a schema file:
  • The first line must be dn: cn=schema.
  • The schema file can include both attributes and object classes, but it can also include only one or the other.
  • If both attributes and object classes are defined in the style, all of the attributes must be listed in the file first, then the object classes.
  • The object classes can use attributes defined in other schema files.
  • The file must be named in the format [1-9][0-9]text.ldif.
    The file must always begin with two numbers. Numerically, the schema file cannot be loaded before the core configuration schema (which begin with 00 and 01).
    Also, the Directory Server always writes its custom schema to the numerically and alphabetically highest named schema file in the schema directory. It expects this file to be 99user.ldif. If this file is not 99user.ldif, the server can experience problems. So, always make sure custom schema files are at least alphabetically lower than 99user.ldif. The name 99alpha.ldif is okay; the name 99zzz.ldif is not.
Practices for creating schema files are described in more detail in the Deployment Guide.
Attributes are defined in the schema file as attributetypes attributes to the schema, with five components:
  • An OID, usually a dot-separated number
  • A unique name, in the form NAME name
  • A description, in the form DESC description
  • The OID for the syntax of the attribute values, discussed in Section 12.3, “Directory Server Attribute Syntaxes”, in the form SYNTAX OID
  • Optionally, the source where the attribute is defined
For example:
attributetypes: ( 1.2.3.4.5.6.1 NAME 'dateofbirth' DESC 'For employee birthdays' SYNTAX 1.3.6.1.4.1.1466.115.121.1.15 SINGLE-VALUED X-ORIGIN 'Example defined')
Likewise, object classes are defined as values of objectclasses attributes, although there is slightly more flexibility in how the object class is defined. The only required configurations are the name and OID for the object class; all other configuration depends on the needs for the object class:
  • An OID, usually a dot-separated number
  • A unique name, in the form NAME name
  • A description, in the form DESC description
  • The superior, or parent, object class for this object class, in the form SUP object_class; if there is no related parent, use SUP top
  • The word AUXILIARY, which gives the type of entry to which the object class applies; AUXILIARY means it can apply to any entry
  • A list of required attributes, preceded by the word MUST; to include multiple attributes, enclose the group in parentheses and separate with attributes with dollar signs ($)
  • A list of allowed attributes, preceded by the word MAY; to include multiple attributes, enclose the group in parentheses and separate with attributes with dollar signs ($)
For example:
objectclasses: ( 2.16.840.1133730.2.123 NAME 'examplePerson' DESC 'Example Person Object Class' SUP inetOrgPerson AUXILIARY  MUST cn MAY (exampleDateOfBirth $ examplePreferredOS) )
Example 12.4, “Example Schema File” shows a simplified schema file.

Example 12.4. Example Schema File

dn: cn=schema
attributetypes: ( 2.16.840.1133730.1.123 NAME 'dateofbirth' DESC 'For employee birthdays' SYNTAX 1.3.6.1.4.1.1466.115.121.1.15 X-ORIGIN 'Example defined')
objectclasses: ( 2.16.840.1133730.2.123 NAME 'examplePerson' DESC 'Example Person Object Class' SUP inetOrgPerson AUXILIARY MAY (dateofbirth) )
Custom schema files should be added to the Directory Server instance's schema directory, /etc/dirsrv/slapd-instance/schema. The schema in these files are not loaded and available to the server unless the server is restarted or a dynamic reload task is run.

12.7. Dynamically Reloading Schema

By default, the schema files used by the Directory Server instance are loaded into the directory when it is started. This means that any new schema files added to the schema directory are not available for use unless the server is restarted. The Directory Server has a task which manually reloads the full schema for the Directory Server instance, including custom files, without requiring a server restart.
The schema reload task can be initiated in two ways:
  • Using the schema-reload.pl script
  • Adding a cn=schema reload task entry using ldapmodify

12.7.1. Reloading Schema Using schema-reload.pl

The schema-reload.pl script launches a special task to reload all of the schema files used by a specific Directory Server instance. This allows custom schema files to be loaded dynamically without having to add schema elements to 99user.ldif.
  1. Run the script, binding as the Directory Manager.
    # schema-reload.pl -Z instance_name -D "cn=Directory Manager" -w secret
    The Directory Server responds that it has added the new reload task entry.
    adding new entry cn=schema_reload_2009_1_6_17_52_4,cn=schema reload task,cn=tasks,cn=config
    This reloads the schema from the default schema directory, /etc/dirsrv/slapd-instance/schema, which is recommended. It is also possible to specify a different directory using the -d option.
    # schema-reload.pl -Z instance_name-D "cn=Directory Manager" -w password -d /export/custom-schema

    Important

    The Directory Server schema reload task reloads the schema files from the directory you specified in the schemadir parameter. Additionally, the server loads all schema files from the //usr/share/dirsrv/schema directory.
The schema-reload.pl is described in more detail in the Configuration, Command, and File Reference.

12.7.2. Reloading Schema Using ldapmodify

The schema-reload.pl script creates a special task entry in a Directory Server instance which reloads schema files; it is also possible to reload schema by creating the task entry directly. Task entries occur under the cn=tasks configuration entry in the dse.ldif file, so it is also possible to initiate a task by adding the entry using ldapmodify. As soon as the task is complete, the entry is removed from the directory.
To initiate a schema reload task, add an entry under the cn=schema reload task,cn=tasks,cn=config entry. The only required attribute is the cn for the specific task.
# ldapmodify -a -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: cn=example schema reload,cn=schema reload task,cn=tasks,cn=config
changetype: add
objectclass: extensibleObject
cn:example schema reload
The default schema directory from which the Directory Server instance reloads the schema is in /usr/share/dirsrv/schema; it is possible to specify a different schema directory using the schemadir attribute, which is analogous to the -d option with schema-reload.pl.
# ldapmodify -a -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: cn=example schema reload,cn=schema reload task,cn=tasks,cn=config
changetype: add
objectclass: extensibleObject
cn:example schema reload
schemadir: /etc/dirsrv/slapd-instance_name/schema/

Important

The Directory Server schema reload task reloads the schema files from the directory you specified in the schemadir parameter. Additionally, the server loads all schema files from the //usr/share/dirsrv/schema directory.
As soon as the task is completed, the entry is deleted from the dse.ldif configuration, so it is possible to reuse the same task entry continually.
The cn=schema reload task configuration is described in more detail in the Configuration, Command, and File Reference.

12.7.3. Reloading Schema with Replication

The schema reload task is a local operation, so schema changes are not replicated in a multi-master environment if the schema is added to one supplier but not to the others. To load the new schema files on all of the supplier servers:
  1. Stop replication.
  2. Copy the new schema file over and run the schema reload task for every supplier and replica server.
  3. Restart replication.

12.7.4. Schema Reload Errors

When the schema reload task runs, the command prompt only shows that the task is initiated.
adding new entry cn=schema reload task 1,cn=schema reload task,cn=tasks,cn=config
However, the task does not return whether it completed successfully. To verify the schema reload operation was successful, check the error logs. The schema reload has two tasks, first validating the schema file and then loading it.
A success message shows that the validation passed and the task finished.
[06/Jan/2009:17:52:04.001214874 -0500] schemareload - Schema reload task starts (schema dir: default) ...
[06/Jan/2009:17:52:04.754335904 -0500] schemareload - Schema validation passed.
[06/Jan/2009:17:52:04.894255328 -0500] schemareload - Schema reload task finished.
If there is a failure, then the logs show which step failed and why.
[..] schemareload - Schema reload task starts (schema dir: /bogus) ...
[..] schema - No schema files were found in the directory /bogus
[..] schema_reload - schema file validation failed
[..] schemareload - Schema validation failed.

12.8. Turning Schema Checking On and Off

When schema checking is on, the Directory Server ensures three things:
  • The object classes and attributes using are defined in the directory schema.
  • The attributes required for an object class are contained in the entry.
  • Only attributes allowed by the object class are contained in the entry.

Important

Red Hat recommends not to disable the schema checking.
Schema checking is turned on by default in the Directory Server, and the Directory Server should always run with schema checking turned on. The only situation where is may be beneficial to turn schema checking off is to accelerate LDAP import operations. However, there is a risk of importing entries that do not conform to the schema. Consequently, it is impossible to update these entries.

12.8.1. Turning Schema Checking On and Off Using the Command Line

To turn schema checking on and off using LDAP commands, edit the value of the nsslapd-schemacheck attribute. For example to disable schema checking:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: cn=config
changetype: modify
replace: nsslapd-schemacheck
nsslapd-schemacheck: off
For details about the nsslapd-schemacheck parameter, see the description of the parameter in the Red Hat Directory Server Configuration, Command, and File Reference.

12.8.2. Turning Schema Checking On and Off Using the Console

To enable or disable schema checking using the Console:
  1. In the Directory Server Console, select the Configuration tab.
  2. Highlight the server icon at the top of the navigation tree, then select the Settings tab in the right pane.
  3. To enable schema checking, check the Enable Schema Checking check box; clear it to turn off schema checking.
  4. Click Save.

12.9. Using Syntax Validation

With syntax validation, the Directory Server checks that the value of an attribute follows the rules of the syntax given in the definition for that attribute. For example, syntax validation will confirm that a new telephoneNumber attribute actually has a valid telephone number for its value.

Important

Red Hat recommends not to disable the syntax validation.

12.9.1. About Syntax Validation

As with schema checking, validation reviews any directory modification and rejects changes that violate the syntax. Additional settings can be optionally configured so that syntax validation can log warning messages about syntax violations and then either reject the modification or allow the modification process to succeed.
This feature validates all attribute syntaxes, with the exception of binary syntaxes (which cannot be verified) and non-standard syntaxes, which do not have a defined required format. The syntaxes are validated against RFC 4514.

12.9.2. Syntax Validation and Other Directory Server Operations

Syntax validation is mainly relevant for standard LDAP operations like creating entries (add) or editing attributes (modify). Validating attribute syntax can impact other Directory Server operations, however.
Database Encryption

For normal LDAP operations, an attribute is encrypted just before the value is written to the database. This means That encryption occurs after the attribute syntax is validated.

Encrypted databases (as described in Chapter 10, Configuring Attribute Encryption) can be exported and imported. Normally, it is strongly recommended that these export and import operations are done with the -E flag with db2ldif and ldif2db, which allows syntax validation to occur just fine for the import operation. However, if the encrypted database is exported without using the -E flag (which is not supported), then an LDIF with encrypted values is created. When this LDIF is then imported, the encrypted attributes cannot be validated, a warning is logged, and attribute validation is skipped in the imported entry.
Synchronization

There may be differences in the allowed or enforced syntaxes for attributes in Windows Active Directory entries and Red Hat Directory Server entries. In that case, the Active Directory values could not be properly synced over because syntax validation enforces the RFC standards in the Directory Server entries.

Replication

If the Directory Server 10.3 instance is a supplier which replicates its changes to a consumer, then there is no issue with using syntax validation. However, if the supplier in replication is an older version of Directory Server or has syntax validation disabled, then syntax validation should not be used on the consumer because the Directory Server 10.3 consumer may reject attribute values that the master allows.

12.9.3. Enabling or Disabling Syntax Validation

Syntax validation is configured by the nsslapd-syntaxcheck attribute. The value of this attribute is either on or off (by default, this is on). To change the syntax validation, modify this attribute using ldapmodify or by editing the dse.ldif file directly.
# ldapmodify -D "cn=Directory Manager" -W -x

dn: cn=config
changetype: modify
replace: nsslapd-syntaxcheck
nsslapd-syntaxcheck: off

Note

If syntax validation is disabled, then run the syntax-validate.pl script to audit existing attribute values before re-enabling syntax validation. See Section 12.9.6, “Validating the Syntax of Existing Attribute Values”.

12.9.4. Enabling Strict Syntax Validation for DNs

When syntax validation is enabled, DNs are validated against RFC 4514, as are other attribute syntaxes. However, DN syntax validation is enabled separately because the strictness of later standards can invalidate old-style DNs, and therefore directory trees.
Syntax validation checks DNs against section 3 in RFC 4514.
The value of this attribute is either on or off (by default, this is off). To change the syntax validation, modify this attribute using ldapmodify or by editing the dse.ldif file directly.
# ldapmodify -D "cn=Directory Manager" -W -x

dn: cn=config
changetype: modify
replace: nsslapd-dn-validate-strict
nsslapd-dn-validate-strict: on

Note

If strict DN validation is enabled and a DN value does not conform to the required syntax, then the operation fails with LDAP result code 34, INVALID_DN_SYNTAX.

12.9.5. Enabling Syntax Validation Warnings (Logging)

By default, syntax validation rejects any add or modify operations where an attribute value violates the required syntax. However, the violation itself is not recorded to the errors log by default. The nsslapd-syntaxlogging attribute enables error logging for any syntax violations.

Note

Syntax violations discovered by the syntax validation script and task are logged in the Directory Server error log.
If nsslapd-syntaxlogging and nsslapd-syntaxcheck are both enabled, then any invalid attribute modification is rejected and the message written to the log. If nsslapd-syntaxlogging is enabled but nsslapd-syntaxcheck is disabled, then the operation is allowed to succeed, but the warning message is still written to the error log.
The value of this attribute is either on or off (by default, this is off). To enable syntax validation logging, edit the attribute using ldapmodify or by editing the dse.ldif file directly.
# ldapmodify -D "cn=Directory Manager" -W -x

dn: cn=config
changetype: modify
replace: nsslapd-syntaxlogging
nsslapd-syntaxlogging: on

12.9.6. Validating the Syntax of Existing Attribute Values

In certain situations, you might want to manually validate the syntax of existing values. For example:
To create a task that validates the syntax of all values in the ou=people,dc=example,dc=com sub-tree which match the (objectclass=inetorgperson) filter:
# syntax-validate.pl -D "cn=Directory Manager" -w secret \
     -b "ou=people,dc=example,dc=com" -f "(objectclass=inetorgperson)"
ldap_initialize( ldap://server.example.com:389 )
Successfully added task entry "cn=syntax_validate_2017_7_3_10_52_47, cn=syntax validate, cn=tasks, cn=config"
Directory Server logs the results to the /var/log/dirsrv/slapd-instance_name/errors file. For example:
  • If all verified values are valid:
    [28/Jun/2017:12:52:43.669867966 +0200] - ERR - syntax-plugin - syntax_validate_task_thread - Starting (base: "dc=example,dc=com", filter: "(objectclass=*)") ...
    [28/Jun/2017:12:52:43.696850129 +0200] - ERR - syntax-plugin - syntax_validate_task_thread - Complete.  Found 0 invalid entries.
  • If invalid entries were found:
    [28/Jun/2017:12:54:05.736087520 +0200] - ERR - syntax-plugin - syntax_validate_task_thread - Starting (base: "dc=example,dc=com", filter: "(objectclass=*)") ...
    [28/Jun/2017:12:54:05.754195607 +0200] - ERR - syntax-plugin - syntax_validate_task_callback - Entry "cn=user,ou=People,dc=example,dc=com" violates syntax.
    description: value #0 invalid per syntax
    [28/Jun/2017:12:54:05.759905671 +0200] - ERR - syntax-plugin - syntax_validate_task_thread - Complete.  Found 1 invalid entries.

    Note

    The syntax-validate.pl script only identifies syntax violations. You must fix incorrect values manually.

Chapter 13. Managing Indexes

Indexing makes searching for and retrieving information easier by classifying and organizing attributes or values. This chapter describes the searching algorithm itself, placing indexing mechanisms in context, and then describes how to create, delete, and manage indexes.

13.1. About Indexes

This section provides an overview of indexing in Directory Server. It contains the following topics:

13.1.1. About Index Types

Indexes are stored in files in the directory's databases. The names of the files are based on the indexed attribute, not the type of index contained in the file. Each index file may contain multiple types of indexes if multiple indexes are maintained for the specific attribute. For example, all indexes maintained for the common name attribute are contained in the cn.db file.
Directory Server supports the following types of index:
  • Presence index (pres) contains a list of the entries that contain a particular attribute, which is very useful for searches. For example, it makes it easy to examine any entries that contain access control information. Generating an aci.db file that includes a presence index efficiently performs the search for ACI=* to generate the access control list for the server.
  • Equality index (eq) improves searches for entries containing a specific attribute value. For example, an equality index on the cn attribute allows a user to perform the search for cn=Babs Jensen far more efficiently.
  • Approximate index (approx) is used for efficient approximate or sounds-like searches. For example, an entry may include the attribute value cn=Robert E Lee. An approximate search would return this value for searches against cn~=Robert Lee, cn~=Robert, or cn~=Lee. Similarly, a search against l~=San Fransisco (note the misspelling) would return entries including l=San Francisco.
  • Substring index (sub) is a costly index to maintain, but it allows efficient searching against substrings within entries. Substring indexes are limited to a minimum of three characters for each entry.
    For example, searches of the form cn=*derson , match the common names containing strings such as Bill Anderson, Jill Henderson, or Steve Sanderson. Similarly, the search for telephoneNumber= *555* returns all the entries in the directory with telephone numbers that contain 555.
  • International index speeds up searches for information in international directories. The process for creating an international index is similar to the process for creating regular indexes, except that it applies a matching rule by associating an object identifier (OID) with the attributes to be indexed.
    The supported locales and their associated OIDs are listed in Appendix D, Internationalization. If there is a need to configure the Directory Server to accept additional matching rules, contact Red Hat Consulting.
  • Browsing index, or virtual list view (VLV) index, speeds up the display of entries in the Directory Server Console. This index is particularly useful if a branch of your directory contains hundreds of entries; for example, the ou=people branch. You can create a browsing index on any branch point in the directory tree to improve display performance through the Directory Server Console or by using the vlvindex command-line tool, which is explained in the Red Hat Directory Server Configuration, Command, and File Reference.

13.1.2. About Default and Database Indexes

Directory Server contains a set of default indexes. When you create a new database, Directory Server copies these default indexes from cn=default indexes,cn=config,cn=ldbm database,cn=plugins,cn=config to the new database. Then the database only uses the copy of these indexes, which are stored in cn=index,cn=database_name,cn=ldbm database,cn=plugins,cn=config.
To display the Directory Server default indexes:
# ldapsearch -D "cn=Directory Manager" -W -p 389 -h server.example.com \
     -b "cn=default indexes,cn=config,cn=ldbm database,cn=plugins,cn=config" \
     '(objectClass=nsindex)'

Note

If you update the default index settings stored in cn=default indexes,cn=config,cn=ldbm database,cn=plugins,cn=config, the changes are not applied to the individual databases in cn=index,cn=database_name,cn=ldbm database,cn=plugins,cn=config.
To display the indexes of an individual database:
# ldapsearch -D "cn=Directory Manager" -W -p 389 -h server.example.com \
     -b "cn=index,cn=database_name,cn=ldbm database,cn=plugins,cn=config" \
     '(objectClass=nsindex)'

13.1.3. Overview of the Searching Algorithm

Indexes are used to speed up searches. To understand how the directory uses indexes, it helps to understand the searching algorithm. Each index contains a list of attributes (such as the cn, common name, attribute) and a pointer to the entries corresponding to each value. Directory Serverprocesses a search request as follows:
  1. An LDAP client application sends a search request to the directory.
  2. The directory examines the incoming request to make sure that the specified base DN matches a suffix contained by one or more of its databases or database links.
    • If they do match, the directory processes the request.
    • If they do not match, the directory returns an error to the client indicating that the suffix does not match. If a referral has been specified in the nsslapd-referral attribute under cn=config, the directory also returns the LDAP URL where the client can attempt to pursue the request.
    • The Directory Server examines the search filter to see what indexes apply, and it attempts to load the list of entry IDs from each index that satisfies the filter. The ID lists are combined based on whether the filter used AND or OR joins.
    • If the list of entry IDs is larger than the configured ID list scan limit or if there is no index, then the Directory Server searches every entry in the database. This is an unindexed search.
  3. The Directory Server reads every entry from the id2entry.db database or the entry cache for every entry ID in the ID list (or from the entire database for an unindexed search). The server then checks the entries to see if they match the search filter. Each match is returned as it is found.
    The server continues through the list of IDs until it has searched all candidate entries or until it hits one of the configured resource limits. (Resource limits are listed in Section 14.1.4, “Setting User and Global Resource Limits Using the Command Line”.)

    Note

    It's possible to set separate resource limits for searches using the simple paged results control. For example, administrators can set high or unlimited size and look-through limits with paged searches, but use the lower default limits for non-paged searches.

13.1.4. Approximate Searches

In addition, the directory uses a variation of the metaphone phonetic algorithm to perform searches on an approximate index. Each value is treated as a sequence of words, and a phonetic code is generated for each word.

Note

The metaphone phonetic algorithm in Directory Server supports only US-ASCII letters. Therefore, use approximate indexing only with English values.
Values entered on an approximate search are similarly translated into a sequence of phonetic codes. An entry is considered to match a query if both of the following are true:
  • All of the query string codes match the codes generated in the entry string.
  • All of the query string codes are in the same order as the entry string codes.
Name in the Directory (Phonetic Code) Query String (Phonetic code) Match Comments
Alice B Sarette (ALS B SRT) Alice Sarette (ALS SRT) Matches. Codes are specified in the correct order.
Alice Sarrette (ALS SRT) Matches. Codes are specified in the correct order, despite the misspelling of Sarette.
Surette (SRT) Matches. The generated code exists in the original name, despite the misspelling of Sarette.
Bertha Sarette (BR0 SRT) No match. The code BR0 does not exist in the original name.
Sarette, Alice (SRT ALS) No match. The codes are not specified in the correct order.

13.1.5. Balancing the Benefits of Indexing

Before creating new indexes, balance the benefits of maintaining indexes against the costs.
  • Approximate indexes are not efficient for attributes commonly containing numbers, such as telephone numbers.
  • Substring indexes do not work for binary attributes.
  • Equality indexes should be avoided if the value is big (such as attributes intended to contain photographs or passwords containing encrypted data).
  • Maintaining indexes for attributes not commonly used in a search increases overhead without improving global searching performance.
  • Attributes that are not indexed can still be specified in search requests, although the search performance may be degraded significantly, depending on the type of search.
  • The more indexes you maintain, the more disk space you require.
Indexes can become very time-consuming. For example:
  1. The Directory Server receives an add or modify operation.
  2. The Directory Server examines the indexing attributes to determine whether an index is maintained for the attribute values.
  3. If the created attribute values are indexed, then the Directory Server generates the new index entries.
  4. Once the server completes the indexing, the actual attribute values are created according to the client request.
For example, the Directory Server adds the entry:
dn: cn=John Doe,ou=People,dc=example,dc=com
objectclass: top
objectClass: person
objectClass: orgperson
objectClass: inetorgperson
cn: John Doe
cn: John
sn: Doe
ou: Manufacturing
ou: people
telephoneNumber: 408 555 8834
description: Manufacturing lead for the Z238 line of widgets.
The Directory Server maintains the following indexes:
  • Equality, approximate, and substring indexes for cn (common name) and sn (surname) attributes.
  • Equality and substring indexes for the telephone number attribute.
  • Substring indexes for the description attribute.
When adding that entry to the directory, the Directory Server must perform these steps:
  1. Create the cn equality index entry for John and John Doe.
  2. Create the appropriate cn approximate index entries for John and John Doe.
  3. Create the appropriate cn substring index entries for John and John Doe.
  4. Create the sn equality index entry for Doe.
  5. Create the appropriate sn approximate index entry for Doe.
  6. Create the appropriate sn substring index entries for Doe.
  7. Create the telephone number equality index entry for 408 555 8834.
  8. Create the appropriate telephone number substring index entries for 408 555 8834.
  9. Create the appropriate description substring index entries for Manufacturing lead for the Z238 line of widgets. A large number of substring entries are generated for this string.
As this example shows, the number of actions required to create and maintain databases for a large directory can be resource-intensive.

13.2. Creating Standard Indexes

This section describes how to create presence, equality, approximate, substring, and international indexes for specific attributes using the Directory Server Console and the command line.

Note

When you create a new index type, Directory Server uses this default index as a template for each new database that will be created in future. If you update the default index, the updated settings are not applied to existing databases. To apply a new index to an existing database, un the db2index.pl script or a cn=index,cn=tasks task, as described in Section 13.3, “Generating New Indexes to Existing Databases”.

13.2.1. Creating Indexes from the Server Console

To create presence, equality, approximate, substring, or international indexes:
  1. Select the Configuration tab.
  2. Expand the Data node, expand the suffix of the database to index, and select the database.
  3. Select the Indexes tab in the right pane.

    Note

    Do not click the Database Settings node because this opens the Default Index Settings window, not the window for configuring indexes per database.
  4. If the attribute to be indexed is listed in the Additional Indexes table, go to step 6. Otherwise, click Add Attribute to open a dialog box with a list of all of the available attributes in the server schema.
  5. Select the attribute to index, and click OK.
    The server adds the attribute to the Additional Indexes table.
  6. Select the check box for each type of index to maintain for each attribute.
  7. To create an index for a language other than English, enter the OID of the collation order to use in the Matching Rules field.
    To index the attribute using multiple languages, list multiple OIDs separated by commas, but no whitespace. For a list of languages, their associated OIDs, and further information regarding collation orders, see Appendix D, Internationalization.
  8. Click Save.
The new index is immediately active for any new data that you add and any existing data in your directory. You do not have to restart your server.

13.2.2. Creating Indexes from the Command Line

Note

You cannot create new system indexes because system indexes are hard-coded in Directory Server.
Use ldapmodify to add the new index attributes to your directory.
  • To create a new index that will become one of the default indexes, add the new index attributes to the cn=default indexes,cn=config,cn=ldbm database,cn=plugins,cn=config entry.
  • To create a new index for a particular database, add it to the cn=index,cn=database_name,cn=ldbm database,cn=plugins,cn=config entry, where cn=database_name corresponds to the name of the database.

Note

Avoid creating entries under cn=config in the dse.ldif file. The cn=config entry in the simple, flat dse.ldif configuration file is not stored in the same highly scalable database as regular entries. As a result, if many entries, particularly entries that are likely to be updated frequently, are stored under cn=config, performance will probably suffer. Although we recommend you do not store simple user entries under cn=config for performance reasons, it can be useful to store special user entries such as the Directory Manager entry or replication manager (supplier bind DN) entry under cn=config since this centralizes configuration information.
For information on the LDIF update statements required to add entries, see Section 3.1.4, “Updating a Directory Entry”.
For example, to create presence, equality, and substring indexes for the sn (surname) attribute in the Example1 database:
  1. Run ldapmodify and add the LDIF entry for the new indexes:
    # ldapmodify -a -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn: cn=sn,cn=index,cn=Example1,cn=ldbm database,cn=plugins,cn=config
    changetype: add
    objectClass:top
    objectClass:nsIndex
    cn:sn
    nsSystemIndex:false
    nsIndexType:pres
    nsIndexType:eq
    nsIndexType:sub
    nsMatchingRule:2.16.840.1.113730.3.3.2.3.1
    The cn attribute contains the name of the attribute to index, in this example the sn attribute. The entry is a member of the nsIndex object class. The nsSystemIndex attribute is false, indicating that the index is not essential to Directory Server operations. The multi-valued nsIndexType attribute specifies the presence (pres), equality (eq) and substring (sub) indexes. Each keyword has to be entered on a separate line. The nsMatchingRule attribute in the example specifies the OID of the Bulgarian collation order; the matching rule can indicate any possible value match, such as languages or other formats like date or integer.
    You can use the keyword none in the nsIndexType attribute to specify that no indexes are to be maintained for the attribute. This example temporarily disables the sn indexes on the Example1 database by changing the nsIndexType to none:
    dn: cn=sn,cn=index,cn=Example1,cn=ldbm database,cn=plugins,cn=config
    objectClass:top
    objectClass:nsIndex
    cn:sn
    nsSystemIndex:false
    nsIndexType:none
For a complete list of matching rules and their OIDs, see Section 14.4.4, “Using Matching Rules”, and for the index configuration attributes, see the Red Hat Directory Server Configuration, Command, and File Reference.

Note

Always use the attribute's primary name (not the attribute's alias) when creating indexes. The primary name of the attribute is the first name listed for the attribute in the schema; for example, uid for the user ID attribute.

13.3. Generating New Indexes to Existing Databases

New indexes are not added to existing databases automatically. They must be added manually, and Directory Server has two methods for generating new indexes to an existing database: running the db2index.pl script or running a cn=index,cn=tasks task.

Important

Before you regenerate the index, searches will fail.

13.3.1. Running the db2index.pl Script

After creating an indexing entry or adding additional index types to an existing indexing entry, run the db2index.pl script to generate the new set of indexes to be maintained by the Directory Server. After the script is run, the new set of indexes is active for any new data added to the directory and any existing data in the directory.
Run the db2index.pl Perl script.
# db2index.pl -Z instance_name -D "cn=Directory Manager" -w secret -n ExampleServer -t sn
For more information about using this Perl script, see the Red Hat Directory Server Configuration, Command, and File Reference.
For information about the parameters used in the example, see the description of the db2index utility in the Red Hat Directory Server Configuration, Command, and File Reference.

13.3.2. Using a cn=tasks Entry to Create an Index

The cn=tasks,cn=config entry in the Directory Server configuration is a container entry for temporary entries that the server uses to manage tasks. Several common directory tasks have container entries under cn=tasks,cn=config. Temporary task entries can be created under cn=index,cn=tasks,cn=config to initiate an indexing operation.
This task entry requires a unique name (cn) and a definition for the attribute and type of index, set in nsIndexAttribute in the format attribute:index_type.
For example:
# ldapmodify -a -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: cn=example presence index,cn=index,cn=tasks,cn=config
changetype: add
objectclass: top
objectclass: extensibleObject
cn: example presence index
nsInstance: userRoot
nsIndexAttribute: "cn:pres"
There are three possible index_types:
  • pres for presence indexes
  • eq for equality indexes
  • sub for substring indexes
As soon as the task is completed, the entry is removed from the directory configuration.
For details about the attributes used in the example and other attributes you can set in this entry, see the cn=task_name,cn=index,cn=tasks,cn=config entry description in the Red Hat Directory Server Configuration, Command, and File Reference.

13.4. Creating Browsing (VLV) Indexes

A virtual list view (VLV) index is a way of creating a truncated list for faster searching while enhancing server performance. The VLV index itself can be resource-intensive to maintain, but it can be beneficial in large directories (over 1000 entries).
A browsing index is a type of VLV index that organizes the entries listed into alphabetical order, making it easier to find entries.
VLV indexes are not applied to attributes, like standard indexes are, but they are dynamically generated based on attributes set in entries and the location of those entries in the directory tree. VLV indexes, unlike standard indexes, are special entries in the database rather than configuration settings for the database.

Note

VLV indexes are similar to simple paged results, which can be returned with some external LDAP clients. Simple paged results are calculated per search, while VLV indexes are a permanent list, so VLV indexes are overall faster for searches, but do require some overhead for the server to maintain.
Simple paged results and VLV indexes cannot be used on the same search.

13.4.1. Creating Browsing Indexes from the Server Console

  1. Select the Directory tab.
  2. In the left navigation tree, select the entry, such as People, for which to create the index.
  3. From the Object menu, select Create Browsing Index.
    The Create Browsing Index dialog box appears displaying the status of the index creation. Click the Status Logs box to view the status of the indexes created.
  4. Click Close.
The new index is immediately active for any new data that is added to the directory. You do not have to restart your server.
For more information on how to change the VLV search information or the access control rules that are set by default for VLV searches, see Section 13.4.2.1, “Adding a Browsing Index Entry” and Section 13.4.3, “Setting Access Control for VLV Information”.

13.4.2. Creating Browsing Indexes from the Command Line

Creating a browsing index or virtual list view (VLV) index from the command line has these steps:
  1. Using ldapmodify to add new browsing index entries or edit existing browsing index entries. See Section 13.4.2.1, “Adding a Browsing Index Entry”.
  2. Running the vlvindex script to generate the new set of browsing indexes to be maintained by the server. See Section 13.4.2.2, “Running the vlvindex Script”. Alternatively, launch an appropriate task under cn=tasks,cn=config (Section 13.4.2.3, “Using a cn=tasks Entry to Create a Browsing Index”).
  3. Ensuring that access control on VLV index information is set appropriately. See Section 13.4.3, “Setting Access Control for VLV Information”.

13.4.2.1. Adding a Browsing Index Entry

The type of browsing index entry to create depends on the type of ldapsearch attribute sorting to accelerate. It is important to take the following into account:
  • The scope of the search (base, one, sub)
  • The base of the search (the entry to use as a starting point for the search)
  • The attributes to sort
  • The filter of the search
    For more information on specifying filters for searches, see Chapter 14, Finding Directory Entries.
  • The LDBM database to which the entry that forms the base of the search belongs. You can only create browsing indexes in LDBM databases.
For example, create a browsing index to accelerate an ldapsearch on the entry ou=People,dc=example,dc=com held in the Example1 database with the following attributes:
  • The search base is ou=People,dc=example,dc=com
  • The search filter is (|(objectclass=*)(objectclass=ldapsubentry))
  • The scope is one
  • The sorting order for the returned attributes is cn, givenname, o, ou, and sn
  1. Run ldapmodify and add an entry which specifies the base, scope, and filter of the browsing index:
    # ldapmodify -a -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn: cn=MCC ou=People dc=example dc=com,cn=userRoot,cn=ldbm database,cn=plugins,cn=config
    changetype: add
    objectClass: top
    objectClass: vlvSearch
    cn: MCC ou=People dc=example dc=com
    vlvBase: ou=People,dc=example,dc=com
    vlvScope: 1
    vlvFilter: (|(objectclass=*)(objectclass=ldapsubentry))
    • The cn contains the browsing index identifier, which specifies the entry on which to create the browsing index; in this example, the ou=People,dc=example,dc=com entry. Red Hat recommends using the dn of the entry for the browsing index identifier, which is the approach adopted by the Directory Server Console, to prevent identical browsing indexes from being created. The entry is a member of the vlvSearch object class.
    • The vlvbase attribute value specifies the entry on which you want to create the browsing index; in this example, the ou=People,dc=example,dc=com entry (the browsing index identifier).
    • The vlvScope attribute is 1, indicating that the scope for the search you want to accelerate is 1. A search scope of 1 means that only the immediate children of the entry specified in the cn attribute, and not the entry itself, will be searched.
    • The vlvFilter specifies the filter to be used for the search; in this example, (|(objectclass=*)(objectclass=ldapsubentry)).
  2. Add the second entry, to specify the sorting order for the returned attributes:
    dn: cn=by MCC ou=People dc=example dc=com,cn=MCC ou=People
       dc=example dc=com,cn=userRoot,cn=ldbm database,cn=plugins,
       cn= config
    objectClass: top
    objectClass: vlvIndex
    cn: by MCC ou=People dc=example dc=com
    vlvSort: cn givenName o ou sn
    • The cn contains the browsing index sort identifier. The above cn is the type created by the Console by default, which has the sorting order as being set by the browsing index base. The entry is a member of the vlvIndex object class.
    • The vlvSort attribute value specifies the order in which you want your attributes to be sorted; in this example, cn, givenName, o, ou, and then sn.

Note

This first browsing index entry must be added to the cn=database_name,cn=ldbm database,cn=plugins,cn=config directory tree node, and the second entry must be a child of the first entry.

13.4.2.2. Running the vlvindex Script

After creating the two browsing indexing entries or added additional attribute types to an existing indexing browsing entries, run the vlvindex script to generate the new set of browsing indexes to be maintained by the Directory Server. After running the script, the new set of browsing indexes is active for any new data added to the directory and any existing data in the directory.
To run the vlvindex script:
  1. Stop the server.
    # systemctl stop dirsrv@instance_name
  2. Run the vlvindex script.
    # vlvindex -Z instance_name -n Example1 -T "by MCC ou=people dc=example dc=com"
    For information about the parameters used in the example, see the description of the vlvindex script in the Red Hat Directory Server Configuration, Command, and File Reference.
  3. Start the server.
    # systemctl start dirsrv instance

13.4.2.3. Using a cn=tasks Entry to Create a Browsing Index

As an alternative to running the vlvindex script, it is possible to initiate an indexing task directly.

Note

Running the indexing task is the same as running the vlvindex script.
The cn=tasks,cn=config entry in the Directory Server configuration is a container entry for temporary entries that the server uses to manage tasks. Several common directory tasks have container entries under cn=tasks,cn=config. Temporary task entries can be created under cn=index,cn=tasks,cn=config to initiate an indexing operation.
This task entry requires a unique name (cn) and one other attribute, nsIndexVLVAttribute, which gives the name of the browsing index definition entry to use to generate the VLV index.
For example:
# ldapmodify -a -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: cn=example VLV index,cn=index,cn=tasks,cn=config
changetype: add
objectclass: extensibleObject
cn: example VLV index
nsIndexVLVAttribute: "by MCC ou=people,dc=example,dc=com"
As soon as the task is completed, the entry is removed from the directory configuration.
The Red Hat Directory Server Configuration, Command, and File Reference has more information on running Directory Server tasks under the cn=tasks entries.

13.4.3. Setting Access Control for VLV Information

The default access control instruction (ACI) allows only authenticated users to use the VLV index information. If you additionally require to allow non-authenticated users to use the VLV index information, update the aci attribute to set the userdn parameter to ldap://anyone:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: oid=2.16.840.1.113730.3.4.9,cn=features,cn=config
changetype: modify
replace: aci
aci: aci: (targetattr != "aci")(version 3.0; acl "VLV Request Control";
     allow( read, search, compare, proxy ) userdn = "ldap://anyone" ;)

13.5. Changing the Index Sort Order

By default, indexes are sorted alphabetically, in descending ASCII order. This is true for every attribute, even attributes which may have numeric attribute values like Integer or TelephoneNumber. It is possible to change the sort method by changing the matching rule set for the attribute.

13.5.1. Changing the Sort Order in the Console

  1. Select the Configuration tab.
  2. Expand the Data node, expand the suffix of the database to index, and select the database.
  3. Select the Indexes tab in the right pane.
  4. Select the index, and, in the Matching Rules field, enter the new sort order to use. For example, to sort by numbers, rather than alphabetically, enter integerOrderingMatch.
  5. Click Save.

13.5.2. Changing the Sort Order in the Command Line

To change the sort order using the command line, change the nsMatchingRule for the attribute index. For example:
# ldapmodify -D "cn=Directory Manager" -W -x

dn: cn=sn,cn=index,cn=Example1,cn=ldbm database,cn=plugins,cn=config
changetype:modify
replace:nsMatchingRule
nsMatchingRule:integerOrderingMatch

13.7. Deleting Indexes

This section describes how to remove attributes and index types from the index.

13.7.1. Deleting an Attribute from the Default Index Entry

When using the default settings of Directory Server, several attributes listed in the default index entry, such as sn, are indexed. The following attributes are part of the default index:

Table 13.1. Default Index Attributes

aci
cn
entryusn
givenName
mail
mailAlternateAddress
mailHost
member
memberOf
nsUniqueId
ntUniqueId
ntUserDomainId
numsubordinates
objectclass
owner
parentid
seeAlso
sn
telephoneNumber
uid
uniquemember

Warning

Removing system indexes can significantly affect the Directory Server performance.
For example, to remove the sn attribute from the default index:
  1. Remove the attribute from the cn=default indexes,cn=config,cn=ldbm database,cn=plugins,cn=config entry:
    # ldapdelete -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    cn=sn,cn=default indexes,cn=config,cn=ldbm database,cn=plugins,cn=config
    If you do not remove the attribute from this entry, the index for the sn attribute is automatically recreated and corrupted after the server is restarted.
  2. Remove the cn=attribute_name,cn=index,cn=userRoot,cn=ldbm database,cn=plugins,cn=config entry. For details, see:
  3. Run the db2index.pl Perl script to recreate the index:
    # db2index.pl -Z instance_name -D "cn=Directory Manager" -w secret -n database_name
    For further information about using the db2index.pl Perl script, see the db2index.pl(8) man page.

13.7.2. Removing an Attribute from the Index Using the Server Console

The Directory Server Console can delete any custom indexes, indexes used by other server applications such as a messaging or web server, and default indexes.
To remove an attribute from the index:
  1. If the attribute to remove is listed in the cn=default indexes,cn=config,cn=ldbm database,cn=plugins,cn=config default index entry, remove it from this entry first. For details, see Section 13.7.1, “Deleting an Attribute from the Default Index Entry”.
  2. Select the Configuration tab.
  3. Expand the Data node and expand the suffix associated with the database containing the index.
  4. Select the database from which to delete the index.
  5. Locate the attribute containing the index to delete. Clear the check box under the index.
    To delete all indexes maintained for a particular attribute, select the attribute's cell under Attribute Name, and click Delete Attribute.
  6. Click Save.
    A Delete Index warning dialog box opens, requiring a confirmation to delete the index.
  7. Click Yes to delete the index.

13.7.3. Removing an Attribute from the Index Using the Command Line

In certain situations you want to remove an attribute from the index. For example, to remove the sn attribute:
  1. If the attribute to remove is listed in the cn=default indexes,cn=config,cn=ldbm database,cn=plugins,cn=config default index entry, you must remove it from this entry first. For details, see Section 13.7.1, “Deleting an Attribute from the Default Index Entry”.
  2. Remove the attribute from the index:
    # ldapdelete -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    cn=sn,cn=index,cn=database_name,cn=ldbm database,cn=plugins,cn=config
    After deleting the entry, the index for the sn attribute is no longer maintained.
  3. Run the db2index.pl Perl script to recreate the index.
    # db2index.pl -Z instance_name -D "cn=Directory Manager" -w secret -n database_name
    For further information about using the db2index.pl Perl script, see the db2index.pl(8) man page.

13.7.4. Deleting Index Types from the Command Line

For example, to remove the sub index type of the sn attribute from the index:
  1. Remove the index type:
    # ldapmodify -D "cn=Directory Manager" -W -x
    dn: cn=sn,cn=index,cn=database_name,cn=ldbm database,cn=plugins,cn=config
    
    changetype: modify
    delete: nsIndexType
    nsIndexType:sub
    After deleting the index entry, the substring index for the sn attribute is no longer maintained.
  2. Run the db2index.pl Perl script to recreate the index. For example:
    # db2index.pl -Z instance_name -D "cn=Directory Manager" -w secret -n database_name
    For further information about using the db2index.pl Perl script, see the db2index.pl(8) man page.

13.7.5. Deleting Browsing Indexes from the Server Console

  1. Select the Directory tab.
  2. Select the entry from which to delete the index in the navigation tree, and select Delete Browsing Index from the Object menu.
    Alternatively, select and right-click the entry of the index to delete in the navigation tree, and then choose Delete Browsing Index from the pop-up menu.
  3. A Delete Browsing Index dialog box appears asking you to confirm the deletion of the index. Click Yes.
  4. The Delete Browsing Index dialog box appears displaying the status of the index deletion.

13.7.6. Deleting Browsing Indexes from the Command Line

Deleting a browsing index or virtual list view (VLV) index from the command line involves two steps:
  1. Using the ldapdelete to delete browsing index entries or edit existing browsing index entries (Section 13.7.6.1, “Deleting a Browsing Index Entry”).
  2. Running the vlvindex script to generate the new set of browsing indexes to be maintained by the server (Section 13.7.6.2, “Running the vlvindex Script”). Alternatively, launch an appropriate task under cn=tasks,cn=config (Section 13.4.2.3, “Using a cn=tasks Entry to Create a Browsing Index”).
The actual entries for an alphabetical browsing index and virtual list view are the same. The following sections describe the steps involved in deleting browsing indexes.

13.7.6.1. Deleting a Browsing Index Entry

Use the ldapdelete command-line utility to either delete browsing indexing entries or edit existing browsing index entries. To delete browsing indexes for a particular database, remove the browsing index entries from the cn=index,cn=database_name,cn=ldbm database,cn=plugins,cn=config entry, where cn=database_name corresponds to the name of the database.
For example, there is a browsing index for accelerating ldapsearch operations on the entry ou=People,dc=example,dc=com. It held in the Example1 database where the search base is ou=People,dc=example,dc=com, the search filter is (|(objectclass=*)(objectclass=ldapsubentry)), the scope is 1, and the sorting order for the returned attributes is cn, givenname, o, ou, and sn.
To delete this browsing index, delete the two corresponding browsing index entries:
dn: cn=MCC ou=People dc=example dc=com,cn=userRoot,cn=ldbm database,cn=plugins,cn=config
objectClass: top
objectClass: vlvSearch
cn: MCC ou=People dc=example dc=com
vlvBase: ou=People,dc=example,dc=com
vlvScope: 1 vlvFilter: (|(objectclass=*)(objectclass=ldapsubentry))

dn: cn=by MCC ou=People dc=example dc=com,cn=MCC ou=People
dc=example dc=com,cn=userRoot,cn=ldbm database,cn=plugins,cn=config
objectClass: top
objectClass: vlvIndex
cn: by MCC ou=People dc=example dc=com
vlvSort: cn givenname o ou sn
Run ldapdelete, specifying both entries.
# ldapdelete -D "cn=Directory Manager" -W -p 389 -h server.example.com -x "cn=MCC ou=People dc=example dc=com,cn=userRoot,cn=ldbm database,cn=plugins,cn=config" "cn=by MCC ou=People dc=example dc=com,cn=MCC ou=People dc=example dc=com,cn=userRoot,cn=ldbm database,cn=plugins,cn=config"
After deleting the two browsing index entries, the browsing index will no longer be maintained by the Example1 database.

13.7.6.2. Running the vlvindex Script

After deleting browsing indexing entries or unwanted attribute types from existing browsing indexing entries, run the vlvindex script to generate the new set of browsing indexes to be maintained by the Directory Server. After the script is run, the new set of browsing indexes is active for any new data added to the directory and any existing data in the directory.
  1. Stop the server.
    # systemctl stop dirsrv.target instance
  2. Run the vlvindex script.
    # vlvindex -Z instance_name -n Example1 -T "by MCC ou=people dc=example dc=com"
    For information about the parameters used in the example, see the description of the vlvindex script in the Red Hat Directory Server Configuration, Command, and File Reference.
  3. Restart the server.
    # systemctl start dirsrv.target instance
Alternatively, create a new task entry under cn=index,cn=tasks,cn=config to initiate an indexing operation. This task entry requires a unique name (cn) and one other attribute, nsIndexVLVAttribute, which gives the name of the browsing index definition entry to use to generate the VLV index. This task is the same as running vlvindex.
For example:
# ldapmodify -a -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: cn=example VLV index,cn=index,cn=tasks,cn=config
changetype: add
objectclass: extensibleObject
cn: example VLV index
nsIndexVLVAttribute: "by MCC ou=people,dc=example,dc=com"
As soon as the task is completed, the entry is removed from the directory configuration.
For details about the attributes used in the example and other attributes you can set in this entry, see the cn=task_name,cn=index,cn=tasks,cn=config entry description in the Red Hat Directory Server Configuration, Command, and File Reference.

Chapter 14. Finding Directory Entries

Entries in the directory can be searched for and found using any LDAP client. Most clients provide some form of search interface so that the directory can be searched easily and entry information can be easily retrieved.

14.1. Improving Search Performance through Resource Limits

With large directories, searching through every entry in the database can have a negative impact on the server performance. Effective indexing can improve the performance in certain scenarios. However, in large databases, this may still not reduce the search scope enough to improve the performance.
Reasonable limits can be set on user and client accounts to reduce the total number of entries or the total amount of time spent in an individual search, which both makes searches more responsive and improves overall server performance.
Server limits for search operations are controlled using special operational attribute values on the client application binding to the directory. You can set the following search operation limits:
  • Look through limit. Specifies how many entries can be examined for a search operation.
  • Size limit. Specifies the maximum number of entries the server returns to a client application in response to a search operation.
  • Time limit. Specifies the maximum time the server spends processing a search operation.
  • Idle timeout. Specifies the time a connection to the server can be idle before the connection is dropped.
  • Range timeout. Specifies a separate look-through limit specifically for searches using a range.
The resource limits set for the client application take precedence over the default resource limits set for in the global server configuration.

Note

The Directory Manager receives unlimited resources by default, with the exception of range searches.

14.1.1. Search Performance and Resource Limits

For details, see the corresponding section in the Red Hat Directory Server Performance Tuning Guide.

14.1.2. Fine Grained ID List Size

For details, see the corresponding section in the Red Hat Directory Server Performance Tuning Guide.

14.1.3. Setting Resource Limits on a Single User

  1. Select the Directory tab.
  2. Browse the navigation tree in the left navigation pane, and double-click the user or role for which to set resource limits.
    The Edit Entry dialog box appears.
  3. Click Account in the left pane.
  4. Set the resource limits. There are four different limits that can be set:
    • Look through limit. The maximum number of entries are examined for a search operation.
    • Size limit. The maximum number of entries the server returns to a client application in response to a search operation.
    • Time limit. The maximum time the server spends processing a search operation.
    • Idle timeout. The time a connection to the server can be idle before the connection is dropped.
    Entering a value of -1 indicates no limit.
  5. Click OK.

14.1.4. Setting User and Global Resource Limits Using the Command Line

More options are available when setting resource limits in the command line than through the Directory Server Console. The Directory Server Console sets user-level resource limits. Through the command line, administrators can set user-level resource limits, global resource limits, and limits for specific kinds of searches, such as simple paged and range searches. Section 13.1.3, “Overview of the Searching Algorithm” has more information on how these resource limits affect Directory Server search performance.
Section 14.1.4, “Setting User and Global Resource Limits Using the Command Line” lists operational attributes which can be set for each entry using the command line. Use ldapmodify to add the attributes to the entry.
User-level attributes are set on the individual entries, while global configuration attributes are set in the appropriate server configuration area.
Look-through limit
Specifies how many entries are examined for a search operation. Giving this attribute a value of -1 indicates that there is no limit.
  • User-level attribute: nsLookThroughLimit
  • Global configuration:
    • Attribute: nsslapd-lookthroughlimit
    • Entry: cn=config,cn=ldbm database,cn=plugins,cn=config
Page look-through limit
As with the look-through limit, specifies how many entries are examined, but specifically for simple paged search operations. Giving this attribute a value of -1 indicates that there is no limit.
  • User-level attribute: nsPagedLookThroughLimit
  • Global configuration:
    • Attribute: nsSizeLimit
    • Entry: cn=config
Size limit
Specifies the maximum number of entries the server returns to a client application in response to a search operation. Giving this attribute a value of -1 indicates that there is no limit.
  • User-level attribute: nsSizeLimit
  • Global configuration:
    • Attribute: nsslapd-sizelimit
    • Entry: cn=config
Paged size limit
As with the size limit, specifies the maximum number of entries the server returns to a client application but only for simple paged search operations. Giving this attribute a value of -1 indicates that there is no limit.
  • User-level attribute: nsPagedSizeLimit
  • Global configuration:
    • Attribute: nsslapd-pagedsizelimit
    • Entry: cn=config
Time Limit
Specifies the maximum time the server spends processing a search operation. Giving this attribute a value of -1 indicates that there is no time limit.
  • User-level attribute: nsTimeLimit
  • Global configuration:
    • Attribute: nsslapd-timelimit
    • Entry: cn=config
Idle timeout
Specifies the time a connection to the server can be idle before the connection is dropped. The value is given in seconds. Giving this attribute a value of -1 indicates that there is no limit.
  • User-level attribute: nsidletimeout
  • Global configuration:
    • Attribute: nsslapd-idletimeout
    • Entry: cn=config
ID list scan limit
Specifies the maximum number of entry IDs loaded from an index file for search results. If the ID list size is greater than this value, the search will not use the index list but will treat the search as an unindexed search and look through the entire database.
  • User-level attribute: nsIDListScanLimit
  • Global configuration:
    • Attribute: nsslapd-idlistscanlimit
    • Entry: cn=config,cn=ldbm database,cn=plugins,cn=config
Paged ID list scan limit
As with the ID list scan limit, specifies the maximum number of entry IDs loaded from an index file for search results, but specifically for paged search operations.
  • User-level attribute: nsPagedIDListScanLimit
  • Global configuration:
    • Attribute: nsslapd-pagedidlistscanlimit
    • Entry: cn=config,cn=ldbm database,cn=plugins,cn=config
Range look-through limit
Specifies how many entries are examined for a range search operation (a search using greater-than, equal-to-or-greater-than, less-than, or equal-to-less-than operators). Giving this attribute a value of -1 indicates that there is no limit.
  • User-level attribute: not available
  • Global configuration:
    • Attribute: nsslapd-rangelookthroughlimit
    • Entry: cn=config,cn=ldbm database,cn=plugins,cn=config
For information about the parameters listed above, see their descriptions in the Red Hat Directory Server Configuration, Command, and File Reference.
For example, this sets the size limit for Barbara Jensen by using ldapmodify to modify her entry:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: uid=user_name,ou=People,dc=example,dc=com
changetype: modify
add: nsSizeLimit
nsSizeLimit: 500
The ldapmodify statement adds the nsSizeLimit attribute to Babs Jensen's entry and gives it a search return size limit of 500 entries.

Note

Set an access control list (ACL) to prevent users changing the setting. For details about ACLs, see Chapter 18, Managing Access Control.

14.1.5. Setting Resource Limits on Anonymous Binds

Resource limits are set on a user entry. An anonymous bind, obviously, does not have a user entry associated with it. This means that the global resource limits usually apply to anonymous operations. However, it is possible to configure resource limits specifically for anonymous binds by creating a template user entry that has resource limits, and then applying that template to anonymous binds.
  1. Create a template entry and set whatever resource limits you want to apply to anonymous binds.

    Note

    For performance reasons, the template should be in the normal back end, not in the cn=config suffix, which does not use an entry cache.
    For example:
    # ldapmodify -a -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn: cn=anon template,ou=people,dc=example,dc=com
    changetype: add
    objectclass: nsContainer
    objectclass: top
    cn: anon template
    nsSizeLimit: 250
    nsLookThroughLimit: 1000
    nsTimeLimit: 60
  2. On all masters in a replication topology, add the nsslapd-anonlimitsdn to the server configuration, pointing to the DN of the template entry. Any of the resource limits in Section 14.1.4, “Setting User and Global Resource Limits Using the Command Line” can be set. For example:
    # ldapmodify -D "cn=Directory Manager" -W -x
    
    dn: cn=config
    changetype: modify
    add: nsslapd-anonlimitsdn
    nsslapd-anonlimitsdn: cn=anon template,ou=people,dc=example,dc=com

14.1.6. Improving Performance for Range Searches

Range searches use operators (Section 14.4.2, “Using Operators in Search Filters”) to set a bracket to search for and return an entire subset of entries within the directory. For example, this searches for every entry modified at or after midnight on January 1:
(modifyTimestamp>=20180101010101Z)
The nature of a range search is that it must evaluate every single entry within the directory to see if it is within the range given. Essentially, a range search is always an all IDs search.
For most users, the look-through limit kicks in and prevents range searches from turning into an all IDs search. This improves overall performance and speeds up range search results. However, some clients or administrative users like Directory Manager may not have a look-through limit set. In that case, a range search can take several minutes to complete or even continue indefinitely.
It is possible to set a separate range look-through limit. This allows clients and administrative users to have high look-through limits while still allowing a reasonable limit to be set on potentially performance-impaired range searches.
This is configured in the nsslapd-rangelookthroughlimit attribute. The default value is 5000, the same as the default nsslapd-lookthroughlimit attribute value.
For example:
# ldapmodify -a -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: cn=config,cn=ldbm database,cn=plugins,cn=config
changetype: add
add: nsslapd-rangelookthroughlimit
nsslapd-rangelookthroughlimit: 7500

14.2. Finding Entries Using the Directory Server Console

Users can browse the Directory tab of the Directory Server Console to see the contents of the directory tree and search for specific entries in the directory.
Browsing Entries in the Directory Tab

Figure 14.1. Browsing Entries in the Directory Tab

Depending on the DN used to authenticate to the directory, this tab displays the contents of the directory that the user account has access permissions to view. Browse through the contents of the tree, or right-click an entry, and select Search from the pop-up menu.
Searching for Entries

Figure 14.2. Searching for Entries

Warning

Do not modify the contents of the o=NetscapeRoot suffix using the Directory tab unless instructed to do so by Red Hat technical support.

14.3. Using ldapsearch

The ldapsearch command-line utility can locate and retrieve directory entries. This utility opens a connection to the specified server using the specified identity and credentials and locates entries based on a specified search filter. The search scope can include a single entry (-s base), an entry's immediate subentries (-s one), or an entire tree or subtree (-s sub).

Note

A common mistake is to assume that the directory is searched based on the attributes used in the distinguished name. The distinguished name is only a unique identifier for the directory entry and cannot be used as a search key. Instead, search for entries based on the attribute-data pairs stored on the entry itself. Thus, if the distinguished name of an entry is uid=bjensen,ou=People,dc=example,dc=com, then a search for dc=example does not match that entry unless dc:example has explicitly been added as an attribute in that entry.
Search results are returned in LDIF format. LDIF is defined in RFC 2849 and is described in detail in Appendix B, LDAP Data Interchange Format.
This section contains information about the following topics:

14.3.1. ldapsearch Command-Line Format

The ldapsearch command must use the following format:
# ldapsearch [-x | -Y mechanism] [options] [search_filter] [list_of_attributes]
  • Either -x (to use simple binds) or -Y (to set the SASL mechanism) must be used to configure the type of connection.
  • options is a series of command-line options. These must be specified before the search filter, if any are used.
  • search_filter is an LDAP search filter as described in Section 14.4, “LDAP Search Filters”. Do not specify a separate search filter if search filters are specified in a file using the -f option.
  • list_of_attributes is a list of attributes separated by a space. Specifying a list of attributes reduces the number of attributes returned in the search results. This list of attributes must appear after the search filter. For an example, see Section 14.5.6, “Displaying Subsets of Attributes”. If a list of attributes is not specified, the search returns values for all attributes permitted by the access control set in the directory, with the exception of operational attributes.
    For operational attributes to be returned as a result of a search operation, hey must be explicitly specified in the search command. To return all operational attributes of an object specify +. To retrieve regular attributes in addition to explicitly specified operational attributes, use an asterisk (*) in the list of attributes in the ldapsearch command.
    To retrieve only a list of matching DNs, use the special attribute 1.1. For example:
    # ldapsearch -D "cn=Directory Manager" -W -p 389 -h server.example.com \
         -b "dc=example,dc=com" -x ""(objectclass=inetorgperson)"" 1.1

14.3.2. Commonly Used ldapsearch Options

The following table lists the most commonly used ldapsearch command-line options. If a specified value contains a space ( ), the value should be surrounded by single or double quotation marks, such as -b "cn=My Special Group,ou=groups,dc=example,dc=com".

Important

The ldapsearch utility from OpenLDAP uses SASL connections by default. To perform a simple bind or to use TLS, use the -x argument to disable SASL and allow other connection methods.
Option Description
-b Specifies the starting point for the search. The value specified here must be a distinguished name that currently exists in the database. This is optional if the LDAP_BASEDN environment variable has been set to a base DN. The value specified in this option should be provided in single or double quotation marks. For example:
-b "cn=Barbara Jensen,ou=Product Development,dc=example,dc=com"
To search the root DSE entry, specify an empty string here, such as -b "" .
-D Specifies the distinguished name with which to authenticate to the server. This is optional if anonymous access is supported by the server. If specified, this value must be a DN recognized by the Directory Server, and it must also have the authority to search for the entries. For example, -D "uid=bjensen,dc=example,dc=com".
-H
Specifies an LDAP URL to use to connect to the server. For a traditional LDAP URL, this has the following format:
ldap[s]://hostname[:port]
The port is optional; it will use the default LDAP port of 389 or LDAPS port of 636 if the port is not given.
This can also use an LDAPI URL, with each element separated by the HTML hex code %2F, rather than a forward slash (/):
ldapi://%2Ffull%2Fpath%2Fto%2Fslapd-example.socket
For LDAPI, specify the full path and filename of the LDAPI socket the server is listening to. Since this value is interpreted as an LDAP URL, the forward slash characters (/) in the path and filename must be escaped encoded as the URL escape value %2F.
The -H option is used instead of -h and -p.
-h Specifies the host name or IP address of the machine on which the Directory Server is installed. For example, -h server.example.com. If a host is not specified, ldapsearch uses the localhost.

Note

Directory Server supports both IPv4 and IPv6 addresses.
-l Specifies the maximum number of seconds to wait for a search request to complete. For example, -l 300. The default value for the nsslapd-timelimit attribute is 3600 seconds. Regardless of the value specified, ldapsearch will never wait longer than is allowed by the server's nsslapd-timelimit attribute.
-p Specifies the TCP port number that the Directory Server uses. For example, -p 1049. The default is 389.
If -h is specified, -p must also be specified, even if it gives the default value.
-s scope Specifies the scope of the search. The scope can be one of the following:
base searches only the entry specified in the -b option or defined by the LDAP_BASEDN environment variable.
one searches only the immediate children of the entry specified in the -b option. Only the children are searched; the actual entry specified in the -b option is not searched.
sub searches the entry specified in the -b option and all of its descendants; that is, perform a subtree search starting at the point identified in the -b option. This is the default.
-W
Prompt for the password. If this option is not set, anonymous access is used.
Alternatively, use the -w option to pass the password to the utility. Note that the password can be visible in the process list for other users and is saved in the shell's history.
-x Disables the default SASL connection to allow simple binds.
-Y SASL_mechanism
Sets the SASL mechanism to use for authentication. If no mechanism is set, ldapsearch selects the best mechanism supported by the server.
If If -x is not used, then the -Y option must be used.
-z number Sets the maximum number of entries to return in a response to a search request. This value overwrites the server-side nsslapd-sizelimit parameter when binding using the root DN. wibrown>

14.3.3. Using Special Characters

When using the ldapsearch command-line utility, it may be necessary to specify values that contain characters that have special meaning to the command-line interpreter, such as space ( ), asterisk (*), or backslash (\). Enclose the value which has the special character in quotation marks (""). For example:
-D "cn=Barbara Jensen,ou=Product Development,dc=example,dc=com"
Depending on the command-line interpreter, use either single or double quotation marks. In general, use single quotation marks (') to enclose values. Use double quotation marks (") to allow variable interpolation if there are shell variables. Refer to the operating system documentation for more information.

14.4. LDAP Search Filters

Search filters select the entries to be returned for a search operation. They are most commonly used with the ldapsearch command-line utility. When using ldapsearch, there can be multiple search filters in a file, with each filter on a separate line in the file, or a search filter can be specified directly on the command line.
The basic syntax of a search filter is:
attribute operator value 
For example:
buildingname>=alpha
In this example, buildingname is the attribute, >= is the operator, and alpha is the value. Filters can also be defined that use different attributes combined together with Boolean operators.

Note

When performing a substring search using a matching rule filter, use the asterisk (*) character as a wildcard to represent zero or more characters.
For example, to search for an attribute value that starts with the letter l and ends with the letter n, enter a l*n in the value portion of the search filter. Similarly, to search for all attribute values beginning with the letter u, enter a value of u* in the value portion of the search filter.
To search for a value that contains the asterisk (*) character, the asterisk must be escaped with the designated escape sequence, \5c2a. For example, to search for all employees with businessCategory attribute values of Example*Net product line, enter the following value in the search filter:
Example\5c2a*Net product line

Note

A common mistake is to assume that the directory is searched based on the attributes used in the distinguished name. The distinguished name is only a unique identifier for the directory entry and cannot be used as a search key. Instead, search for entries based on the attribute-data pairs stored on the entry itself. Thus, if the distinguished name of an entry is uid=bjensen,ou=People,dc=example,dc=com, then a search for dc=example does not match that entry unless dc:example has explicitly been added as an attribute in that entry.

14.4.1. Using Attributes in Search Filters

The most basic sort of search looks for the presence of attributes or specific values in entries. There are many variations on how to look for attributes in entries. It is possible to check that the attribute merely exists, to match an exact value, or to list matches against a partial value.
A presence search uses a wild card (an asterisk) to return every entry which has that attribute set, regardless of value. For example, this returns every entry which has a manager attribute:
"(manager=*)"
It is also possible to search for an attribute with a specific value; this is called an equality search. For example:
"(cn=babs jensen)"
This search filter returns all entries that contain the common name Babs Jensen. Most of the time, equality searches are not case sensitive.
When an attribute has values associated with a language tag, all of the values are returned. Thus, the following two attribute values both match the "(cn=babs jensen)" filter:
cn: babs jensen
cn;lang-fr: babs jensen
It is also possible to search for a partial match on an attribute value, a substring index. For example:
"(description=*X.500*)"
"(sn=*nderson)"
"(givenname=car*)"
The length of the substring searches is configured in the substring index itself, as described in Section 13.6, “Changing the Width for Indexed Substring Searches”.

14.4.2. Using Operators in Search Filters

Operators in search filters set the relationship between the attribute and the given search value. For people searches, operators can be used to set a range, to return a last names within a subset of letters in the alphabet or employee numbers that come after a certain number.
"(employeeNumber>=500)"
"(sn~=suret)"
"(salary<=150000)"
Operators also enable phonetic and approximate searches, which allow more effective searches with imperfect information and are particularly useful in internationalized directories.
The operators that can be used in search filters are listed in Table 14.1, “Search Filter Operators”. In addition to these search filters, special filters can be specified to work with a preferred language collation order. For information on how to search a directory with international charactersets, see Section D.4, “Searching an Internationalized Directory”.

Table 14.1. Search Filter Operators

Search Type Operator Description
Equality = Returns entries containing attribute values that exactly match the specified value. For example, cn=Bob Johnson
Substring =string* string Returns entries containing attributes containing the specified substring. For example, cn=Bob* cn=*Johnson cn=*John* cn=B*John. The asterisk (*) indicates zero (0) or more characters.
Greater than or equal to >= Returns entries containing attributes that are greater than or equal to the specified value. For example, buildingname >= alpha.
Less than or equal to <= Returns entries containing attributes that are less than or equal to the specified value. For example, buildingname <= alpha.
Presence =* Returns entries containing one or more values for the specified attribute. For example, cn=* telephoneNumber=* manager=*.
Approximate ~= Returns entries containing the specified attribute with a value that is approximately equal to the value specified in the search filter. For example, cn~=suret l~=san fransico could return cn=sarette l=san francisco.

14.4.3. Using Compound Search Filters

Multiple search filter components can be combined using Boolean operators expressed in prefix notation as follows:
(Boolean-operator(filter)(filter)(filter)...)
Boolean-operator is any one of the Boolean operators listed in Table 14.2, “Search Filter Boolean Operators”.
FOr example, this filter returns all entries that do not contain the specified value:
(!(cn=Ray Kultgen))
(!(objectClass=person))
Obviously, compound search filters are most useful when they are nested together into completed expressions:
(Boolean-operator(filter)((Boolean-operator(filter)(filter)))
These compound filters can be combined with other types of searches (approximate, substring, other operators) to get very detailed results. For example, this filter returns all entries whose organizational unit is Marketing and whose description field does not contain the substring X.500:
(&(ou=Marketing)(!(description=*X.500*)))
That filter can be expanded to return entries whose organizational unit is Marketing, that do not have the substring X.500, and that have Julie Fulmer or Cindy Zwaska as a manager:
(&(ou=Marketing)(!(description=*X.500*))(|(manager=cn=Julie Fulmer,ou=Marketing,dc=example,dc=com)(manager=cn=Cindy Zwaska,ou=Marketing,dc=example,dc=com)))
This filter returns all entries that do not represent a person and whose common name is similar to printer3b:
(&(!(objectClass=person))(cn~=printer3b))

Table 14.2. Search Filter Boolean Operators

Operator Symbol Description
AND & All specified filters must be true for the statement to be true. For example, (&(filter)(filter)(filter)...).
OR | At least one specified filter must be true for the statement to be true. For example, (|(filter)(filter)(filter)...)
NOT ! The specified statement must not be true for the statement to be true. Only one filter is affected by the NOT operator. For example, (!(filter)).
Boolean expressions are evaluated in the following order:
  • Innermost to outermost parenthetical expressions first.
  • All expressions from left to right.

14.4.4. Using Matching Rules

A matching rule tells the Directory Server how to compare two values (the value stored in the attribute and the value in the search filter). A matching rule also defines how to generate index keys. Matching rules are somewhat related to attribute syntaxes. Syntaxes define the format of an attribute value; matching rules define how that format is compared and indexed.
There are three different types of matching rules:
  • EQUALITY specifies how to compare two values for an equal match. For example, how to handle strings like "Fred" and "FRED". Search filters that test for equality (for example, attribute=value) use the EQUALITY rule. Equality (eq) indexes use the EQUALITY rule to generate the index keys. Update operations use the EQUALITY rule to compare values to be updated with values already in an entry.
  • ORDERING specifies how to compare two values to see if one value is greater or less than another value. Search filters that set a range (for example, attribute<=value or attribute>=value) use the ORDERING rule. An index for an attribute with an ORDERING rule orders the equality values.
  • SUBSTR specifies how to do substring matching. Substring search filters (for example, attribute=*partial_string* or attribute=*end_string) use the SUBSTR rule. Substring (sub) indexes use the SUBSTR rule to generate the index keys.

Important

A matching rule is required in order to support searching or indexing for the corresponding search filter or index type. For example, an attribute must have an EQUALITY matching rule in order to support equality search filters and eq indexes for that attribute. An attribute must have both an ORDERING matching rule and an EQUALITY matching rule in order to support range search filters and indexed range searches.
A search operation will be rejected with PROTOCOL_ERROR or UNWILLING_TO_PERFORM if an attempt is made to use a search filter for an attribute that has no corresponding matching rule.

Example 14.1. Matching Rules and Custom Attributes

Example Corp. administrators create a custom attribute type called MyFirstName with IA5 String (7-bit ASCII) syntax and an EQUALITY matching rule of caseExactIA5Match. An entry with a MyFirstName value of Fred is returned in a search with a filter of (MyFirstName=Fred), but it is not returned for filters like (MyFirstName=FRED) and (MyFirstName=fred) Fred, FRED, and fred are all valid IA5 String values, but they do not match using the caseExactIA5Match rule.
For all three variants of Fred to be returned in a search, then the MyFirstName should be defined to use the caseIgnoreIA5Match matching rule.
An extensible matching rule search filter can be used to search for an attribute value with a different matching rule than the one defined for the attribute. The matching rule must be compatible with the syntax of the attribute being searched. For example, to run a case insensitive search for an attribute that has a case-sensitive matching rule defined for it, specify a case insensitive matching rule in the search filter.
(MyFirstName:caseIgnoreIA5Match:=fred)

Note

Matching rules are used for searches in internationalized directories, to specify the language types to use for the results. This is covered in Section D.4, “Searching an Internationalized Directory”.

Note

An index for an attributes uses whatever matching rules are defined for that attribute in its schema definition. Additional matching rules to use for an index can be configured using the nsMatchingRule attribute, as in Section 13.2.2, “Creating Indexes from the Command Line”.
The syntax of the matching rule filter inserts a matching rule name or OID into the search filter:
attr:matchingRule:=value
  • attr is an attribute belonging to entries being searched, such as cn or mail.
  • matchingRule is a string that contains the name or OID of the rule to use to match attribute values according to the required syntax.
  • value is either the attribute value to search for or a relational operator plus the attribute value to search for. The syntax of the value of the filter depends on the matching rule format used.
A matching rule is actually a schema element, and, as with other schema elements is uniquely identified by an object identifier (OID).
Many of the matching rules defined for Red Hat Directory Server relate to language codes and set internationalized collation orders supported by the Directory Server. For example, the OID 2.16.840.1.113730.3.3.2.17.1 identifies the Finnish collation order.

Note

Unlike other schema elements, additional matching rules cannot be added to the Directory Server configuration.
Most of the matching rules list in following list are used for equality indexes. Matching rules with ordering in their name are used for ordering indexes, and those with substring in their name are used for substring (SUBSTR) indexes. (The matching rules used for international matching and collation orders use a different naming scheme.)
Bitwise AND match
Performs bitwise AND matches.
OID: 1.2.840.113556.1.4.803
Compatible syntaxes: Typically used with Integer and numeric strings. Directory Server converts numeric strings automatically to integer.
Bitwise OR match
Performs bitwise OR matches.
OID: 1.2.840.113556.1.4.804
Compatible syntaxes: Typically used with Integer and numeric strings. Directory Server converts numeric strings automatically to integer.
booleanMatch
Evaluates whether the values to match are TRUE or FALSE
OID: 2.5.13.13
Compatible syntaxes: Boolean
caseExactIA5Match
Makes a case-sensitive comparison of values.
OID: 1.3.6.1.4.1.1466.109.114.1
Compatible syntaxes: IA5 Syntax, URI
caseExactMatch
Makes a case-sensitive comparison of values.
OID: 2.5.13.5
Compatible syntaxes: Directory String, Printable String, OID
caseExactOrderingMatch
Allows case-sensitive ranged searches (less than and greater than).
OID: 2.5.13.6
Compatible syntaxes: Directory String, Printable String, OID
caseExactSubstringsMatch
Performs case-sensitive substring and index searches.
OID: 2.5.13.7
Compatible syntaxes: Directory String, Printable String, OID
caseIgnoreIA5Match
Performs case-insensitive comparisons of values.
OID: 1.3.6.1.4.1.1466.109.114.2
Compatible syntaxes: IA5 Syntax, URI
caseIgnoreIA5SubstringsMatch
Performs case-insensitive searches on substrings and indexes.
OID: 1.3.6.1.4.1.1466.109.114.3
Compatible syntaxes: IA5 Syntax, URI
caseIgnoreListMatch
Performs case-insensitive comparisons of values.
OID: 2.5.13.11
Compatible syntaxes: Postal address
caseIgnoreListSubstringsMatch
Performs case-insensitive searches on substrings and indexes.
OID: 2.5.13.12
Compatible syntaxes: Postal address
caseIgnoreMatch
Performs case-insensitive comparisons of values.
OID: 2.5.13.2
Compatible syntaxes: Directory String, Printable String, OID
caseIgnoreOrderingMatch
Allows case-insensitive ranged searches (less than and greater than).
OID: 2.5.13.3
Compatible syntaxes: Directory String, Printable String, OID
caseIgnoreSubstringsMatch
Performs case-insensitive searches on substrings and indexes.
OID: 2.5.13.4
Compatible syntaxes: Directory String, Printable String, OID
distinguishedNameMatch
Compares distinguished name values.
OID: 2.5.13.1
Compatible syntaxes: Distinguished name (DN)
generalizedTimeMatch
Compares values that are in a Generalized Time format.
OID: 2.5.13.27
Compatible syntaxes: Generalized Time
generalizedTimeOrderingMatch
Allows ranged searches (less than and greater than) on values that are in a Generalized Time format.
OID: 2.5.13.28
Compatible syntaxes: Generalized Time
integerMatch
Evaluates integer values.
OID: 2.5.13.14
Compatible syntaxes: Integer
integerOrderingMatch
Allows ranged searches (less than and greater than) on integer values.
OID: 2.5.13.15
Compatible syntaxes: Integer
keywordMatch
Compares the given search value to a string in an attribute value.
OID: 2.5.13.33
Compatible syntaxes: Directory String
numericStringMatch
Compares more general numeric values.
OID: 2.5.13.8
Compatible syntaxes: Numeric String
numericStringOrderingMatch
Allows ranged searches (less than and greater than) on more general numeric values.
OID: 2.5.13.9
Compatible syntaxes: Numeric String
numericStringSubstringMatch
Compares more general numeric values.
OID: 2.5.13.10
Compatible syntaxes: Numeric String
objectIdentifierMatch
Compares object identifier (OID) values.
OID: 2.5.13.0
Compatible syntaxes: OID
octetStringMatch
Evaluates octet string values.
OID: 2.5.13.17
Compatible syntaxes: Octet String
octetStringOrderingMatch
Supports ranged searches (less than and greater than) on a series of octet string values.
OID: 2.5.13.18
Compatible syntaxes: Octet String
telephoneNumberMatch
Evaluates telephone number values.
OID: 2.5.13.20
Compatible syntaxes: Telephone Number
telephoneNumberSubstringsMatch
Performs substring and index searches on telephone number values.
OID: 2.5.13.21
Compatible syntaxes: Telephone Number
uniqueMemberMatch
Compares both name and UID values.
OID: 2.5.13.23
Compatible syntaxes: Name and Optional UID
wordMatch
Compares the given search value to a string in an attribute value. This matching rule is case-insensitive.
OID: 2.5.13.32
Compatible syntaxes: Directory String

Table 14.3. Language Ordering Matching Rules

Matching Rule Object Identifiers (OIDs)
English (Case Exact Ordering Match) 2.16.840.1.113730.3.3.2.11.3
Albanian (Case Insensitive Ordering Match) 2.16.840.1.113730.3.3.2.44.1
Arabic (Case Insensitive Ordering Match) 2.16.840.1.113730.3.3.2.1.1
Belorussian (Case Insensitive Ordering Match) 2.16.840.1.113730.3.3.2.2.1
Bulgarian (Case Insensitive Ordering Match) 2.16.840.1.113730.3.3.2.3.1
Catalan (Case Insensitive Ordering Match) 2.16.840.1.113730.3.3.2.4.1
Chinese - Simplified (Case Insensitive Ordering Match) 2.16.840.1.113730.3.3.2.49.1
Chinese - Traditional (Case Insensitive Ordering Match) 2.16.840.1.113730.3.3.2.50.1
Croatian (Case Insensitive Ordering Match) 2.16.840.1.113730.3.3.2.22.1
Czech (Case Insensitive Ordering Match) 2.16.840.1.113730.3.3.2.5.1
Danish (Case Insensitive Ordering Match) 2.16.840.1.113730.3.3.2.6.1
Dutch (Case Insensitive Ordering Match) 2.16.840.1.113730.3.3.2.33.1
Dutch - Belgian (Case Insensitive Ordering Match) 2.16.840.1.113730.3.3.2.34.1
English - US (Case Insensitive Ordering Match) 2.16.840.1.113730.3.3.2.11.1
English - Canadian (Case Insensitive Ordering Match) 2.16.840.1.113730.3.3.2.12.1
English - Irish (Case Insensitive Ordering Match) 2.16.840.1.113730.3.3.2.14.1
Estonian (Case Insensitive Ordering Match) 2.16.840.1.113730.3.3.2.16.1
Finnish (Case Insensitive Ordering Match) 2.16.840.1.113730.3.3.2.17.1
French (Case Insensitive Ordering Match) 2.16.840.1.113730.3.3.2.18.1
French - Belgian (Case Insensitive Ordering Match) 2.16.840.1.113730.3.3.2.19.1
French - Canadian (Case Insensitive Ordering Match) 2.16.840.1.113730.3.3.2.20.1
French - Swiss (Case Insensitive Ordering Match) 2.16.840.1.113730.3.3.2.21.1
German (Case Insensitive Ordering Match) 2.16.840.1.113730.3.3.2.7.1
German - Austrian (Case Insensitive Ordering Match) 2.16.840.1.113730.3.3.2.8.1
German - Swiss (Case Insensitive Ordering Match) 2.16.840.1.113730.3.3.2.9.1
Greek (Case Insensitive Ordering Match) 2.16.840.1.113730.3.3.2.10.1
Hebrew (Case Insensitive Ordering Match) 2.16.840.1.113730.3.3.2.27.1
Hungarian (Case Insensitive Ordering Match) 2.16.840.1.113730.3.3.2.23.1
Icelandic (Case Insensitive Ordering Match) 2.16.840.1.113730.3.3.2.24.1
Italian (Case Insensitive Ordering Match) 2.16.840.1.113730.3.3.2.25.1
Italian - Swiss (Case Insensitive Ordering Match) 2.16.840.1.113730.3.3.2.26.1
Japanese (Case Insensitive Ordering Match) 2.16.840.1.113730.3.3.2.28.1
Korean (Case Insensitive Ordering Match) 2.16.840.1.113730.3.3.2.29.1
Latvian, Lettish (Case Insensitive Ordering Match) 2.16.840.1.113730.3.3.2.31.1
Lithuanian (Case Insensitive Ordering Match) 2.16.840.1.113730.3.3.2.30.1
Macedonian (Case Insensitive Ordering Match) 2.16.840.1.113730.3.3.2.32.1
Norwegian (Case Insensitive Ordering Match) 2.16.840.1.113730.3.3.2.35.1
Norwegian - Bokmul (Case Insensitive Ordering Match) 2.16.840.1.113730.3.3.2.36.1
Norwegian - Nynorsk (Case Insensitive Ordering Match) 2.16.840.1.113730.3.3.2.37.1
Polish (Case Insensitive Ordering Match) 2.16.840.1.113730.3.3.2.38.1
Romanian (Case Insensitive Ordering Match) 2.16.840.1.113730.3.3.2.39.1
Russian (Case Insensitive Ordering Match) 2.16.840.1.113730.3.3.2.40.1
Serbian - Cyrillic (Case Insensitive Ordering Match) 2.16.840.1.113730.3.3.2.45.1
Serbian - Latin (Case Insensitive Ordering Match) 2.16.840.1.113730.3.3.2.41.1
Slovak (Case Insensitive Ordering Match) 2.16.840.1.113730.3.3.2.42.1
Slovenian (Case Insensitive Ordering Match) 2.16.840.1.113730.3.3.2.43.1
Spanish (Case Insensitive Ordering Match) 2.16.840.1.113730.3.3.2.15.1
Swedish (Case Insensitive Ordering Match) 2.16.840.1.113730.3.3.2.46.1
Turkish (Case Insensitive Ordering Match) 2.16.840.1.113730.3.3.2.47.1
Ukrainian (Case Insensitive Ordering Match) 2.16.840.1.113730.3.3.2.48.1

Table 14.4. Language Substring Matching Rules

Matching Rule Object Identifiers (OIDs)
English (Case Exact Substring Match) 2.16.840.1.113730.3.3.2.11.3.6
Albanian (Case Insensitive Substring Match) 2.16.840.1.113730.3.3.2.44.1.6
Arabic (Case Insensitive Substring Match) 2.16.840.1.113730.3.3.2.1.1.6
Belorussian (Case Insensitive Substring Match) 2.16.840.1.113730.3.3.2.2.1.6
Bulgarian (Case Insensitive Substring Match) 2.16.840.1.113730.3.3.2.3.1.6
Catalan (Case Insensitive Substring Match) 2.16.840.1.113730.3.3.2.4.1.6
Chinese - Simplified (Case Insensitive Substring Match) 2.16.840.1.113730.3.3.2.49.1.6
Chinese - Traditional (Case Insensitive Substring Match) 2.16.840.1.113730.3.3.2.50.1.6
Croatian (Case Insensitive Substring Match) 2.16.840.1.113730.3.3.2.22.1.6
Czech (Case Insensitive Substring Match) 2.16.840.1.113730.3.3.2.5.1.6
Danish (Case Insensitive Substring Match) 2.16.840.1.113730.3.3.2.6.1.6
Dutch (Case Insensitive Substring Match) 2.16.840.1.113730.3.3.2.33.1.6
Dutch - Belgian (Case Insensitive Substring Match) 2.16.840.1.113730.3.3.2.34.1.6
English - US (Case Insensitive Substring Match) 2.16.840.1.113730.3.3.2.11.1.6
English - Canadian (Case Insensitive Substring Match) 2.16.840.1.113730.3.3.2.12.1.6
English - Irish (Case Insensitive Substring Match) 2.16.840.1.113730.3.3.2.14.1.6
Estonian (Case Insensitive Substring Match) 2.16.840.1.113730.3.3.2.16.1.6
Finnish (Case Insensitive Substring Match) 2.16.840.1.113730.3.3.2.17.1.6
French (Case Insensitive Substring Match) 2.16.840.1.113730.3.3.2.18.1.6
French - Belgian (Case Insensitive Substring Match) 2.16.840.1.113730.3.3.2.19.1.6
French - Canadian (Case Insensitive Substring Match) 2.16.840.1.113730.3.3.2.20.1.6
French - Swiss (Case Insensitive Substring Match) 2.16.840.1.113730.3.3.2.21.1.6
German (Case Insensitive Substring Match) 2.16.840.1.113730.3.3.2.7.1.6
German - Austrian (Case Insensitive Substring Match) 2.16.840.1.113730.3.3.2.8.1.6
German - Swiss (Case Insensitive Substring Match) 2.16.840.1.113730.3.3.2.9.1.6
Greek (Case Insensitive Substring Match) 2.16.840.1.113730.3.3.2.10.1.6
Hebrew (Case Insensitive Substring Match) 2.16.840.1.113730.3.3.2.27.1.6
Hungarian (Case Insensitive Substring Match) 2.16.840.1.113730.3.3.2.23.1.6
Icelandic (Case Insensitive Substring Match) 2.16.840.1.113730.3.3.2.24.1.6
Italian (Case Insensitive Substring Match) 2.16.840.1.113730.3.3.2.25.1.6
Italian - Swiss (Case Insensitive Substring Match) 2.16.840.1.113730.3.3.2.26.1.6
Japanese (Case Insensitive Substring Match) 2.16.840.1.113730.3.3.2.28.1.6
Korean (Case Insensitive Substring Match) 2.16.840.1.113730.3.3.2.29.1.6
Latvian, Lettish (Case Insensitive Substring Match) 2.16.840.1.113730.3.3.2.31.1.6
Lithuanian (Case Insensitive Substring Match) 2.16.840.1.113730.3.3.2.30.1.6
Macedonian (Case Insensitive Substring Match) 2.16.840.1.113730.3.3.2.32.1.6
Norwegian (Case Insensitive Substring Match) 2.16.840.1.113730.3.3.2.35.1.6
Norwegian - Bokmul (Case Insensitive Substring Match) 2.16.840.1.113730.3.3.2.36.1.6
Norwegian - Nynorsk (Case Insensitive Substring Match) 2.16.840.1.113730.3.3.2.37.1.6
Polish (Case Insensitive Substring Match) 2.16.840.1.113730.3.3.2.38.1.6
Romanian (Case Insensitive Substring Match) 2.16.840.1.113730.3.3.2.39.1.6
Russian (Case Insensitive Substring Match) 2.16.840.1.113730.3.3.2.40.1.6
Serbian - Cyrillic (Case Insensitive Substring Match) 2.16.840.1.113730.3.3.2.45.1.6
Serbian - Latin (Case Insensitive Substring Match) 2.16.840.1.113730.3.3.2.41.1.6
Slovak (Case Insensitive Substring Match) 2.16.840.1.113730.3.3.2.42.1.6
Slovenian (Case Insensitive Substring Match) 2.16.840.1.113730.3.3.2.43.1.6
Spanish (Case Insensitive Substring Match) 2.16.840.1.113730.3.3.2.15.1.6
Swedish (Case Insensitive Substring Match) 2.16.840.1.113730.3.3.2.46.1.6
Turkish (Case Insensitive Substring Match) 2.16.840.1.113730.3.3.2.47.1.6
Ukrainian (Case Insensitive Substring Match) 2.16.840.1.113730.3.3.2.48.1.6

14.5. Examples of Common ldapsearches

The next set of examples assumes the following:
  • The search is for all entries in the directory.
  • The directory is configured to support anonymous access for search and read. This means that no bind information has to be supplied in order to perform the search. For more information on anonymous access, see Section 18.13.1.1.3, “Granting Anonymous Access”.
  • The server is located on a host named server.example.com.
  • The server uses port number 389. Since this is the default port, the port number does not have to be sent in the search request.
  • TLS is enabled for the server on port 636 (the default LDAPS port number).
  • The suffix under which all data are stored is dc=example,dc=com.

14.5.1. Returning All Entries

Given the previous information, the following call will return all entries in the directory (subject to the configured size and time resource limits):
# ldapsearch -D "cn=Directory Manager" -W -p 389 -h server.example.com -b "dc=example,dc=com" -s sub -x "(objectclass=*)"
"objectclass=*" is a search filter that matches any entry in the directory. Since every entry must have an object class, and the objectclass attribute is always indexed, this is a useful search filter to return every entry.

14.5.2. Specifying Search Filters on the Command Line

A search filter can be specified directly on the command line as long as the filter is enclosed in quotation marks ("filter"). If the filter is supplied with the command, do not specify the -f option. For example:
# ldapsearch -D "cn=Directory Manager" -W -p 389 -h server.example.com -b "dc=example,dc=com" -s sub -x "cn=babs jensen"

14.5.3. Searching the Root DSE Entry

The root DSE is a special entry that contains information about the directory server instance, including all of the suffixes supported by the local Directory Server. This entry can be searched by supplying a search base of "", a search scope of base, and a filter of "objectclass=*". For example:
# ldapsearch -D "cn=Directory Manager" -W -p 389 -h server.example.com -x -b "" -s base "objectclass=*"

14.5.4. Searching the Schema Entry

The cn=schema entry is a special entry that contains information about the directory schema, such as object classes and attribute types.
The following command lists the content of the cn=schema entry:
# ldapsearch -o ldif-wrap=no -D "cn=Directory Manager" -W -b "cn=schema" \
    '(objectClass=subSchema)' -s sub objectClasses attributeTypes matchingRules \
    matchingRuleUse  dITStructureRules nameForms ITContentRules ldapSyntaxes

14.5.5. Using LDAP_BASEDN

To make searching easier, it is possible to set the search base using the LDAP_BASEDN environment variable. Doing this means that the search base does not have to be set with the -b option. For information on how to set environment variables, see the documentation for the operating system.
Typically, set LDAP_BASEDN to the directory's suffix value. Since the directory suffix is equal to the root, or topmost, entry in the directory, this causes all searches to begin from the directory's root entry.
For example, set LDAP_BASEDN to dc=example,dc=com and search for cn=babs jensen in the directory, use the following command-line call:
# export LDAP_BASEDN="dc=example,dc=com"

# ldapsearch -D "cn=Directory Manager" -W -p 389 -h server.example.com -x "cn=babs jensen"
In this example, the default scope of sub is used because the -s option was not used to specify the scope.

14.5.6. Displaying Subsets of Attributes

The ldapsearch command returns all search results in LDIF format. By default, ldapsearch returns the entry's distinguished name and all of the attributes that a user is allowed to read. The directory access control can be set such that users are allowed to read only a subset of the attributes on any given directory entry. Only operational attributes are not returned. For operational attributes to be returned as a result of a search operation, explicitly specify them in the search command or use + to return all operational attributes.
It may not be necessary to have all of the attributes for an entry returned in the search results. The returned attributes can be limited to just a few specific attributes by specifying the required ones on the command line immediately after the search filter. For example, to show the cn and sn attributes for every entry in the directory, use the following command-line call:
# ldapsearch -D "cn=Directory Manager" -W -p 389 -h server.example.com -b "dc=example,dc=com" -s sub -x "(objectclass=*)" sn cn

14.5.7. Searching for Operational Attributes

Operational attributes are special attributes set by the Directory Server itself that are used by the server to perform maintenance tasks, like processing access control instructions. They also show specific information about the entry, like the time it was initially created and the name of the user who created it. Operational attributes are available for use on every entry in the directory, regardless of whether the attribute is specifically defined for the object class of the entry.
Operational attributes are not returned in regular ldapsearches. According to RFC3673, use + to return all operational attributes in a search request:
# ldapsearch -D "cn=Directory Manager" -W -p 389 -h server.example.com -b "dc=example,dc=com" -s sub -x "(objectclass=*)" '+'
To return only some defined operational attributes, explicitly specify them in the ldapsearch request:
# ldapsearch -D "cn=Directory Manager" -W -p 389 -h server.example.com -b "dc=example,dc=com" -s sub -x "(objectclass=*)" creatorsName createTimestamp modifiersName modifyTimestamp
The complete list of operational attributes is in the "Operational Attributes and Object Classes" chapter in the Red Hat Directory Server 10 Configuration, Command, and File Reference.

Note

To return all of the regular entry attributes along with the specified operational attributes, use the special search attribute, "*", in addition to the operational attributes that are listed.
# ldapsearch -D "cn=Directory Manager" -W -p 389 -h server.example.com -b "dc=example,dc=com" -s sub -x "(objectclass=*)" "*" aci
The asterisk must be enclosed in quotation marks to prevent it from being interpreted by the shell.

14.5.8. Specifying Search Filters Using a File

Search filters can be entered into a file instead of entering them on the command line. In this case, specify each search filter on a separate line in the file. The ldapsearch command runs each search in the order in which it appears in the file.
For example:
sn=Francis
givenname=Richard
ldapsearch first finds all the entries with the surname Francis, then all the entries with the givenname Richard. If an entry is found that matches both search criteria, then the entry is returned twice.
For example, in this search, the filters are specified in a file named searchdb:
# ldapsearch -D "cn=Directory Manager" -W -p 389 -h server.example.com -x -f searchdb
The set of attributes returned here can be limited by specifying the attribute names at the end of the search line. For example, the following ldapsearch command performs both searches but returns only the DN and the givenname and sn attributes of each entry:
# ldapsearch -D "cn=Directory Manager" -W -p 389 -h server.example.com -x -f searchdb sn givenname

14.5.9. Specifying DNs That Contain Commas in Search Filters

When a DN within a search filter contains a comma as part of its value, the comma must be escaped with a backslash (\). For example, to find everyone in the example.com Bolivia, S.A. subtree, use the following command:
# ldapsearch -D "cn=Directory Manager" -W -p 389 -h server.example.com -x -s base -b "l=Bolivia\,S.A.,dc=example,dc=com" "objectclass=*"

14.5.10. Using a Client Certificate to Bind to Directory Server

14.5.11. Searching with Language Matching Rules

To explicitly submit a matching rule in a search filter, insert the matching rule after the attribute:
attr:matchingRule:=value
Matching rules are frequently used for searching internationalized directories. For example, this seearches for the department numbers after N4709 in the Swedish (2.16.840.1.113730.3.3.2.46.1) matching rule.
departmentNumber:2.16.840.1.113730.3.3.2.46.1:=>= N4709
More examples of performing internationalized searches are given in Section D.4, “Searching an Internationalized Directory”.

14.5.12. Searching for Attributes with Bit Field Values

Bitwise searches use the bitwise AND or bitwise OR matching rules to perform bitwise search operaions on attributes with values that are bit fields.

Note

Attributes with values for bit fields are not common in LDAP. (No default Directory Server schema use bit fields as attribute syntax.) However, several LDAP syntaxes support integer-style values. Custom attributes can be defined which use bit field values, and applications can use those custom attributes to perform bitwise operations against bit field values.
The bitwise AND matching rule (1.2.840.113556.1.4.803) checks that the bit given in the assertion value is set in the bit field attribute value. (This is somewhat analogous to an equality search.) In this example, the userAccountControl value must be set to the bit representing 2.
"(UserAccountControl:1.2.840.113556.1.4.803:=2)"
In this example, the userAccountControl value must have all of the bits set that are set in the value 6 (bits 2 and 4).
"(UserAccountControl:1.2.840.113556.1.4.803:=6)”
The bitwise OR matching rule (1.2.840.113556.1.4.804) checks to see if any of the bits in the assertion string are represented in the attribute value. (This is somewhat analogous to a substring search.) In this example, the userAccountControl value must have any of the bits which are set in the bit field of 6, meaning that the attribute value can be 2, 4, or 6.
"(UserAccountControl:1.2.840.113556.1.4.804:=6)"
Bitwise searches can be used with Windows-Red Hat Enterprise Linux integration, such as using Samba file servers.

Note

Microsoft has good documentation on bitwise operators at http://msdn.microsoft.com/en-us/library/aa746475.

14.7. Searching with Specified Controls

The Directory Server has defined controls in its supportedControls attribute in its DSE. Some of these define server operations like replication; other are allowed extended operations like get effective rights or dereferencing controls which clients can pass through LDAP operations to the server.
These controls can be specified using the -E option by giving the control OID, its criticality for the ldapsearch, and any information required for the control operation.
-E '[!]control_OID:control_information'
Some controls, like server-side sorting and simple paged results, have an alias that can be used to pass the control to the search operation. When the control alias is used, then the results are formatted, since the control is recognized by the client.

14.7.1. Retrieving Effective User Rights

A get effective-rights search control is passed using the control OID. For example:
# ldapsearch -D "cn=Directory Manager" -W -p 389 -h server.example.com -b "dc=example,dc=com" -s sub -x -E '!1.3.6.1.4.1.42.2.27.9.5.2:dn:uid=jsmith,ou=people,dc=example,dc=com' "(objectclass=*)"

Important

When a control is passed with its OID, the results from the search are unformatted.
Get effective rights searches are covered in much more detail in the access control chapter, Section 18.14, “Checking Access Rights on Entries (Get Effective Rights)”.

14.7.2. Using Server-Side Sorting

Server-side sorting is performed as other control operations, using the -E flag and the sss control alias. The structure of the operation sets the attribute by which to sort the results and, optionally, the sort order and ordering rule.
-E sss=[-]attribute_name:[ordering_rule_OID]
The dash (-) is an optional flag that reverses the sort order, which naturally runs descending. The matching rule tables in Section 14.4.4, “Using Matching Rules” contain the ordering rules supported by the Directory Server.
For example:
# ldapsearch -D "cn=Directory Manager" -W -p 389 -h server.example.com -b "dc=example,dc=com" -s sub -x -E sss=-uidNumber:2.5.13.15 "(objectclass=*)"

14.7.3. Performing Dereferencing Searches

A dereferencing search is a quick way to track back over cross-references in an entry and return information about the referenced entry. For example, a group entry contains references to its member's user entries. A regular search first searches for the group, then lists its members, and then requires a separate search for each member. A dereferencing search for the group entry returns information about the members — such as their locations, email addresses, or managers — along with the information for the group, all in a single search request.
Dereferencing simplifies many client operations and reduces the number of search operations that are performed. Cross-links show relationships between entries. Some operations may require getting a list of cross-links from one entry and then performing a series of subsequent searches to get information from each entry on the list. Dereferencing allows those sequences of searches to be consolidated into a single search.

Important

Dereferencing operations must be done using OpenLDAP command-line tools version 2.4.18 or later or other clients which support dereferencing searches.
The format of the dereference arguments is:
-E 'deref=deref_attribute:list_of_attributes'
The deref_attribute is the attribute in the search target that contains the reference. This can be any attribute which has a DN for its value, such as member or manager.

Note

Not only must the value of the deref_attribute be a DN, but the actual defined syntax for the attribute must be DN syntax (1.3.6.1.4.1.1466.115.121.1.12).
The list_of_attributes is one or more attributes in the referenced entry which will be returned along with the primary search results. Multiple attributes can be separated by commas, like l,mail,cn.
Simple Dereferencing Search Command

Figure 14.3. Simple Dereferencing Search Command

The requested dereferenced information requested in the search argument is returned with the rest of the search results. For example, this dereferencing search tells the server to use the member attribute in the search target entry (the Engineers group) as the deref_attribute. It then returns the locality attribute for each member.
# ldapsearch -x -D "cn=Directory Manager" -W -b "cn=Example,ou=Groups,dc=example,dc=com" -E 'deref=member:mail,cn' "(objectclass=*)"

# Engineers, Groups, example.com
dn: cn=Engineers,ou=Groups,dc=example,dc=com
control: 1.3.6.1.4.1.4203.666.5.16 false MIQAAADNMIQAAAA1BAZtZW1iZXIEK2NuPURld
 mVsb3BlcnMsIG91PUdyb3VwcywgZGM9ZXhhbXBsZSxkYz1jb20whAAAADIEBm1lbWJlcgQoY249VG
 VzdGVycywgb3U9R3JvdXBzLCBkYz1leGFtcGxlLGRjPWNvbTCEAAAAVAQGbWVtYmVyBCp1aWQ9ZW5
 nLCBvdT1lbmdpbmVlcmluZywgZGM9ZXhhbXBsZSxkYz1jb22ghAAAABowhAAAABQEAWwxhAAAAAsE
 CUNhbWJyaWRnZQ==
# member: <mail=jsmith@example.com><cn=John Smith>;uid=jsmith,ou=people,dc=example,dc=com
 objectClass: top
objectClass: inetuser
objectClass: groupofnames
cn: Engineers
member: uid=jsmith,ou=people,dc=example,dc=com

14.7.4. Using Simple Paged Results

Search results can be very large, and a part of processing the results is organizing the results. One method of doing this is using simple paged results, a control that breaks the results into pages of a certain length.
The simple paged results control sets the number of entries to display at a time. The results can be scrolled through one page at a time which makes the results easier to digest. The full behavior of the control is described in RFC 2696.
Simple paged results are implemented as an LDAP control extension for the Directory Server. Its OID is 1.2.840.113556.1.4.319.
How Simple Paged Results Work

When you start a simple paged results search:

  1. The client sends the search to the server, together with the paged results control and with how many records to return in the first page.
  2. Before Directory Server starts returning data, the server generates an estimate how many records can be returned in total.
    The estimate of records is not an exact number. The total number of records returned can be lower than the estimate. The reasons for such a scenario include
    • attributes used in the search filter do not exist in the index. For an optimal result, all queried attributes must be indexed.
    • before an entry is send to the client, access control lists (ACL) are validated. Insufficient permissions can prevent the entry from being returned.
    After generating the estimate, the server sends the first set of results, a cookie, and the estimated number of records.
  3. The returned records are displayed in the client. The user can now enter how many records should be returned in the next request. The requested number is now sent, together with the cookie, to the server.
  4. The server retrieves the requested number of records from the database and sends them together with a cookie to the client.
  5. The previous two steps are repeated until all records are sent or the search is cancelled.
Simple Paged Results and OpenLDAP Tools

The format of the simple paged result search option with ldapsearch is:

-E pg=size
The size value is the page size, or the number of entries to include per page. For example:
ldapsearch -x -D "cn=Directory Manager" -W -b "ou=Engineers,ou=People,dc=example,dc=com" -E pg=3 "(objectclass=*)" cn

dn: uid=jsmith,ou=Engineers,ou=People,dc=example,dc=com
   cn: John Smith

dn: uid=bjensen,ou=Engineers,ou=People,dc=example,dc=com
   cn: Barbara Jensen

dn: uid=hmartin,ou=Engineers,ou=People,dc=example,dc=com
   cn: Henry Martin

Results are sorted.
next page size (3): 5
The tag at the end shows the configured page size (the number in parentheses) from the search. After the colon, one enters the page size for the next page, so entering 5 as shown would open the next page of results with five entries.

Important

Simple paged results operations must be done using OpenLDAP command-line tools version 2.4.18 or later or other clients which support simple paged results, such as Perl Net::LDAP.
Simple Paged Results and Server-Side Sorting

Simple paged results can be used together with server-side sorting. Server-side sorting is a control which performs the sort process on the server rather than in a client; this is usually done for a search which uses a particular matching rule. (This behavior is defined in RFC 2891.) The OpenLDAP client tools do not support server-side sort with the simple paged results control, but other LDAP utilities such as Perl Net::LDAP do support both.

Multiple Simple Paged Results Requests on a Single Connection

Some clients may open a single connection to the Directory Server, but send multiple operation requests, including multiple search requests using the simple paged results extension.

Directory Server can manage and interpret multiple simple paged searches. Each search is added as an entry in an array. When the paged search request is first sent, there is a cookie created and associated with the search results. Each page of results is returned with that cookie, and that cookie is used to request the next page of results. On the last page, the cookie is empty, signalling the end of the results. This keeps each set of search results separate.
When there are multiple simple paged results on a single connection, the timeout limits are still observed, but all open search requests much reach their configured time limit before any paged search is disconnected.
Simple Paged Results, Contrasted with VLV Indexes

VLV indexes are similar to simple paged results in that they also return a usable browsing list of results. The main difference is in how that list is generated. Simple paged results are calculated per search, while VLV indexes are a permanent list. Overall, VLV indexes are faster for searches, but do require some server-side configuration and overhead for the server to maintain.

Note

Simple paged results and VLV indexes cannot be used on the same search. Simple paged results would attempt to manipulate the VLV index, which is already a browsing index. If the control is passed for a search using a VLV index, then the server returns an UNWILLING_TO_PERFORM error.
For more information on VLV indexes, see Section 13.4, “Creating Browsing (VLV) Indexes”.

14.7.5. Pre- and Post-read Entry Response Controls

Red Hat Directory Server supports pre- and post-read entry response controls according to RFC 4527. If a client requests one or both response controls, an LDAP search entry is returned, that contains the attribute's value before and after the update.
When the pre-read control is used, an LDAP search query is returned containing the specified attribute's value before modification. When the post-read control is used, the query contains the attribute's value after modification. Both controls can be used at the same time. For example, to update the description attribute and display the value before and after the modification:
# ldapmodify -D "cn=Directory Manager" -W -x \
    -e \!preread=description -e \!postread=description 
dn: uid=user,ou=People,dc=example,dc=com
changetype: modify
replace: description
description: new description

modifying entry "uid=user,ou=People,dc=example,dc=com"
control: 1.3.6.1.1.13.1 false ZCkEJXVpZD1qdXNlcixvdT1QZW9wbGUsZGM9ZXhhbXBsZSxk
 Yz1jb20wAA==
# ==> preread
dn: uid=user,ou=People,dc=example,dc=com
description: old description
# <== preread
control: 1.3.6.1.1.13.2 false ZEsEJXVpZD1qdXNlcixvdT1QZW9wbGUsZGM9ZXhhbXBsZSxk
Yz1jb20wIjAgBAtkZXNjcmlwdGlvbjERBA9uZXcgZGVzY3JpcHRpb24=
# ==> postread
dn: uid=user,ou=People,dc=example,dc=com
description: new description
# <== postread

Chapter 15. Managing Replication

Replication is the mechanism by which directory data is automatically synchronized from one Red Hat Directory Server instance to another; it is an important mechanism for extending the directory service beyond a single server configuration. This chapter describes the tasks to be performed on the master and consumer servers to set up single-master replication, multi-master replication, and cascading replication.

15.1. Replication Overview

Replication is the mechanism by which directory data is automatically synchronized from one Directory Server to another. Updates of any kind — entry additions, modifications, or even deletions — are automatically mirrored to other Directory Servers using replication.

15.1.1. What Directory Units Are Replicated

The smallest unit of of the directory which can be replicated is a database. This means that one can replicate an entire database but not a subtree within a database. Therefore, when creating the directory tree, consider any replication plans as part of determining how to distribute information.
Replication also requires that one database correspond to one suffix. This means that a suffix (or namespace) that is distributed over two or more databases using custom distribution logic cannot be replicated. For more information on this topic, see Section 2.2, “Creating and Maintaining Databases”.

15.1.2. Read-Write and Read-Only Replicas

A database that participates in replication is called a replica. There are two kinds of replicas: read-write or read-only. A read-write replica contains master copies of directory information and can be updated. A read-only replica services read, search, and compare requests, but refers all update operations to read-write replicas. A server can hold any number of read-only or read-write replicas.

15.1.3. Suppliers and Consumers

A server that holds a replica that is copied to a replica on a different server is called a supplier for that replica. A server that holds a replica that is copied from a different server is called a consumer for that replica. Generally, the replica on the supplier server is a read-write replica, and the one on the consumer server is a read-only replica, with two exceptions:
Replication is always initiated by the supplier server, never by the consumer (supplier-initiated replication). Supplier-initiated replication allows a supplier server to be configured to push data to multiple consumer servers.

15.1.4. Changelog

Every supplier server maintains a changelog, a record of all changes that a supplier or hub needs to send to its consumers. A changelog is a special kind of database that describes the modifications that have occurred on a replica. The supplier server then replays these modifications to the replicas stored on consumer servers or to other suppliers, in the case of multi-master replication.
When an entry is modified, a change record describing the LDAP operation that was performed is recorded in the changelog.
The changelog uses the same database environment as the main database. Implementing the changelog as part of the main database ensures the database and changelog are always synchronized, reduces the required database cache size, and simplifies backup and restore operations.

Important

The changelog only write RUV entries to the database when the server is shut down, and otherwise the RUVs are managed in memory. When you back up the database of a master, use the db2bak.pl utility or the Directory Server Console. Both ways, the RUVs are written to the database before the backup starts.
In Directory Server, the changelog is only intended for internal use by the server.

15.1.5. Replication Identity

When replication occurs between two servers, the replication process uses a special entry, called the replication manager entry, to identify replication protocol exchanges and to control access to the directory data. The replication manager entry, or any entry used during replication, must meet the following criteria:
  • It is created on the consumer server and not on the supplier server.
  • Create this entry on every server that receives updates from another server, meaning on every hub or dedicated consumer.
  • When a replica is configured as a consumer or hub, this entry must be specified as the one authorized to perform replication updates.
  • The replication agreement is created on the supplier server, the DN of this entry must be specified in the replication agreement.
  • This entry, with its special user profile, bypasses all access control rules defined on the consumer server for the database involved in that replication agreement.

Note

In the Directory Server Console, this replication manager entry is referred to as the supplier bind DN, which may be misleading because the entry does not actually exist on the supplier server. It is called the supplier bind DN because it is the entry which the supplier uses to bind to the consumer. This entry actually exists, then, on the consumer.
For more information on creating the replication manager entry, see Section 15.4, “Creating the Supplier Bind DN Entry”.

15.1.6. Replication Agreement

Directory Servers use replication agreements to define their replication configuration. A replication agreement describes replication between one supplier and one consumer only. The agreement is configured on the supplier server and must specify all required replication information:
  • The database to be replicated.
  • The consumer server to which the data is pushed.
  • The days and times during which replication can occur.
  • The DN and credentials that the supplier server must use to bind (the replication manager entry or supplier bind DN).
  • How the connection is secured (TLS, client authentication).
  • Any attributes that will not be replicated (fractional replication).

15.1.7. Replicating a Subset of Attributes with Fractional Replication

Fractional replication sets a specific subset of attributes that will not be transmitted from a supplier to the consumer (or another supplier). Administrators can therefore replicate a database without replicating all the information that it contains or all of the information in every entry.
Fractional replication is enabled and configured per replication agreement, not per entry. Excluding attributes from replication is applied equally to all entries within the replication agreement's scope.
As far as the consumer server is concerned, the excluded attributes always have no value. Therefore, a client performing a search against the consumer server will never see the excluded attributes. Similarly, should it perform a search that specifies those attributes in its filter, no entries will match.
For attributes that are defined as optional (MAY keyword) in the schema, it is possible to set different attributes to be replicated for an incremental update and a total update. The incremental update list (nsDS5ReplicatedAttributeList) must always be set to enable fractional replication; if that is the only attribute set, then it applies to both incremental and total updates. The optional nsDS5ReplicatedAttributeListTotal attribute sets an additional fractional replication list for total updates. This is described in Section 15.9.1, “Setting Different Fractional Replication Attributes for Total and Incremental Updates”.

Note

An update to an excluded attribute still triggers a modify event and generates an empty replication update. The nsds5ReplicaStripAttrs attribute adds a list of attributes which cannot be sent in an empty replication event and are stripped from the update sequence. This logically includes operational attribtes like modifiersName.
If a replication event is not empty, the stripped attributes are replicated. These attributes are removed from updates only if the event would otherwise be emtpy.

15.1.7.1. The Replication Keep-alive Entry

When you update an attribute on a master, the change sequence number (CSN) is increased on the master. In a replication topology, this server now connects to the first consumer and compares the local CSN with the CSN on the consumer. If it is lower, the update is retrieved from the local changelog and replicated to the consumer. In a replication topology with fractional replication enabled, this can cause problems: For example, if only attributes are updated on the master that are excluded from replication, no update to replicate is found, and therefore the CSN is not updated on the consumer. In certain scenarios, such as when only attributes are updated on a master that are excluded from replication, unnecessary searching for updates on the supplier can cause other servers to receive the data later than needed . To work around this problem, Directory Server uses keep-alive entries.
If all updated attributes on the master are excluded from replication and the number of skipped updates exceeds 100, the keepalivetimestamp attribute is updated on the supplier and replicated to the consumer. Because the keepalivetimestamp attribute is not excluded from replication, the update of the keep-alive entry is replicated, the CSN on the consumer is updated, and then equal to the one on the supplier. The next time the supplier connects to the consumer, only updates that are newer than the CSN on the consumer are searched. This reduces the amount of time spent by a supplier to search for new updates to send.
The replication keep-alive entry is created on demand on a master and contains the replica ID of the master in the distinguished name (DN). Each keep-alive entry is specific to a given master. For example:
dn: cn=repl keep alive 14,dc=example,dc=com
objectclass: top
objectclass: ldapsubentry
objectclass: extensibleObject
cn: repl keep alive 14
keepalivetimestamp: 20170227190346Z
The keep-alive entry is updated in the following situations (if it does not exist before the update, it is created first):
  • When a fractional replication agreement skips more than 100 updates and does not send any updates before ending the replication session.
  • When a master initializes a consumer, initially it creates its own keep-alive entry. A consumer that is also a master does not create its own keep-alive entry unless it also initializes another consumer.

15.2. Configuring Replication from the Command Line

Replication can be configured on the command line by creating the appropriate replica and agreement entries on the servers. The process follows the same order as setting up replication through the Directory Server Console:
  1. Create the supplier bind DN on every consumer, hub, and multi-master supplier (Section 15.4, “Creating the Supplier Bind DN Entry”).
  2. If the corresponding database and suffix do not exist on one of the replicas, create it (Section 2.1.1, “Creating Suffixes”).
  3. Configure hubs for cascading replication (Section 15.2.3, “Configuring Hubs from the Command Line”).
  4. Create the replication agreements (Section 15.2.4, “Configuring Replication Agreements from the Command Line”). For cascading replication, create the agreement between the supplier and hub, then between the hub and consumers; for multi-master, create the agreements between all suppliers, then between the suppliers and consumers.
  5. Lastly, initialize all of the consumers (Section 15.2.5, “Initializing Consumers Online from the Command Line”), if the consumers were not initialized when the replication agreement was created.

15.2.1. Configuring Suppliers from the Command Line

There are two steps to setting up the supplier replica. First, the changelog must be enabled, which allows the supplier to track changes to the Directory Server. Then, the supplier replica is created.
  1. On the supplier server, use ldapmodify to create the changelog entry.

    Example 15.1. Example Changelog Entry

    # ldapmodify -D "cn=Directory Manager" -W -x -h supplier1.example.com -v -a
    
    dn: cn=changelog5,cn=config
    changetype: add
    objectclass: top
    objectclass: extensibleObject
    cn: changelog5
    nsslapd-changelogdir: /var/lib/dirsrv/slapd-instance/changelogdb
    nsslapd-changelogmaxage: 10d
    There are two important attributes with the changelog.
    • nsslapd-changelogdir sets the directory where the changelog is kept.
    • nsslapd-changelogmaxage sets how long the changelog is kept; since the changelog can get very large, this helps trim the changelog to prevent affecting server performance and using up disk space. If this parameter is not set, the default is for the changelog to be kept forever.
    The changelog entry attributes are described in the Red Hat Directory Server Configuration, Command, and File Reference.
  2. Create the supplier replica.

    Example 15.2. Example Supplier Replica Entry

    # ldapmodify -D "cn=Directory Manager" -W -x -h supplier1.example.com -v -a
    
    dn: cn=replica,cn=dc\=example\,dc\=com,cn=mapping tree,cn=config
    changetype: add
    objectclass: top
    objectclass: nsds5replica
    objectclass: extensibleObject
    cn: replica
    nsds5replicaroot: dc=example,dc=com
    nsds5replicaid: 7
    nsds5replicatype: 3
    nsds5flags: 1
    nsds5ReplicaPurgeDelay: 604800
    nsds5ReplicaBindDN: cn=replication manager,cn=config
    The changelog entry attributes are described in the Red Hat Directory Server Configuration, Command, and File Reference.
After creating every supplier which will take part in the replication setup, then begin creating the replication agreements.

15.2.2. Configuring Consumers Using the Command Line

To configure a consumer using the command line, the following settings are required on the consumer host:
  1. Create the replica entry:
    # ldapadd -D "cn=Directory Manager" -W -p 389 -h consumer.example.com -x
    
    dn: cn=replica,cn=dc\=example\,dc\=com,cn=mapping tree,cn=config
    objectclass: top
    objectclass: nsds5replica
    objectclass: extensibleObject
    cn: replica
    nsds5replicaroot: dc=example,dc=com
    nsds5replicaid: 65535
    nsds5replicatype: 2
    nsds5ReplicaBindDN: cn=replication manager,cn=config
    nsds5flags: 0
    This entry identifies the database and suffix as participating in replication and sets what kind of replica the database is.
  2. Set the nsslapd-referral parameter to the LDAP URL of the supplier server and the nsslapd-state to referral on update. For example:
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h consumer.example.com -x
    dn: cn=dc\=example\,dc\=com,cn=mapping tree,cn=config
    changetype: modify
    replace: nsslapd-referral
    nsslapd-referral: ldap://supplier.example.com:389/dc\=example\,dc\=com
    -
    replace: nsslapd-state
    nsslapd-state: referral on update
For further details about the attributes used in the examples, see the corresponding sections in the Red Hat Directory Server Configuration, Command, and File Reference.

15.2.3. Configuring Hubs from the Command Line

Hubs are intermediate read-only replicas which receive updates from suppliers and pass them on to other consumers. These are part of the cascading replication scenario, described in Section 15.3.3, “Cascading Replication”.Creating the hub has two steps: first, creating the changelog database since the hub keeps a record of changes sent by the supplier, and second, configuring the hub replica.
  1. On the hub server, such as hub1.example.com, use ldapmodify to create the changelog entry.
    # ldapmodify -D "cn=Directory Manager" -W -x -h hub1.example.com -v -a
    
    dn: cn=changelog5,cn=config
    changetype: add
    objectclass: top
    objectclass: extensibleObject
    cn: changelog5
    nsslapd-changelogdir: /var/lib/dirsrv/slapd-instance/changelogdb
    There is one important attribute with the changelog, nsslapd-changelogdir, which sets the directory where the changelog is kept.
    The changelog entry attributes are described in the Red Hat Directory Server Configuration, Command, and File Reference.
  2. On the hub host, create the replica entry. This ldapmodify command creates a new hub replica on the hub1.example.com host for the dc=example,dc=com subtree.
    # ldapmodify -D "cn=Directory Manager" -W -x -h hub1.example.com -v -a
    
    dn: cn=replica,cn=dc\=example\,dc\=com,cn=mapping tree,cn=config
    changetype: add
    objectclass: top
    objectclass: nsds5replica
    objectclass: extensibleObject
    cn: replica
    nsds5replicaid: 65535
    nsds5replicaroot: dc=example,dc=com
    nsds5replicatype: 2
    nsds5ReplicaPurgeDelay: 604800
    nsds5ReplicaBindDN: cn=replication manager,cn=config
    nsds5flags: 1
    This entry identifies the database and suffix as participating in replication and sets what kind of replica the database is.
The changelog entry attributes are described in the Red Hat Directory Server Configuration, Command, and File Reference.

15.2.4. Configuring Replication Agreements from the Command Line

When setting up replication agreements, first set them up between all suppliers, then between the suppliers and the hubs, and last between the hub and the consumers.
The replication agreement has to define eight separate attributes:
  • The consumer host (nsds5replicahost) and port (nsds5replicaport).
  • The DN for the supplier to use to bind with the consumer (nsds5ReplicaBindDN).
  • The way that the supplier binds (nsds5replicabindmethod).
  • Any credentials required (nsDS5ReplicaCredentials) for that bind method and specified DN.
  • The subtree being replicated (nsds5replicaroot).
  • The replication schedule (nsds5replicaupdateschedule).
  • Any attributes which will not be replicated (nsds5replicatedattributelist and nsDS5ReplicatedAttributeListTotal).
Use ldapmodify to add a replication agreement to every supplier for every consumer which it will updated. For example:

Example 15.3. Example Replication Agreement Entry

dn: cn=ExampleAgreement,cn=replica,cn=dc\=example\,dc\=com,cn=mapping tree,cn=config
objectclass: top
objectclass: nsds5ReplicationAgreement
cn: ExampleAgreement
nsds5replicahost: consumer1
nsds5replicaport: 389
nsds5ReplicaBindDN: cn=replication manager,cn=config
nsds5replicabindmethod: SIMPLE
nsds5replicaroot: dc=example,dc=com
description: agreement between supplier1 and consumer1
nsds5replicaupdateschedule: 0000-0500 1
nsds5replicatedattributelist: (objectclass=*) $ EXCLUDE authorityRevocationList accountUnlockTime memberof
nsDS5ReplicatedAttributeListTotal: (objectclass=*) $ EXCLUDE accountUnlockTime
nsds5replicacredentials: secret
For descriptions of the parameters used in the example, and additional parameters you can set in the cn=agreement_name,cn=replica,cn=suffix_DN,cn=mapping tree,cn=config entry, see the Red Hat Directory Server Configuration, Command, and File Reference.
After creating every replication agreement, begin initializing consumers.

15.2.4.1. Configuring Replication Partners to use Certificate-based Authentication

Instead of using a bind DN and password to authenticate to a replication partner, you can use certificate-based authentication.
The following procedure describes how to add a new server named server2.example.com to the replication topology and how to set up replication agreements between the new host and the existing server1.example.com using certificate-based authentication:
  1. On both hosts, set up certificate-based authentication. For details, see Section 9.8.1, “Setting up Certificate-based Authentication”.
  2. On the server1.example.com host:
    1. Create accounts for both servers, such as cn=server1,example,dc=com and cn=server2,dc=example,dc=com and add the client certificates to the corresponding accounts. For details, see:
      Both servers will later use these accounts and certificates to authenticate when they establish a replication connection to each other.
    2. Create a group, such as cn=repl_server,ou=Groups,dc=example,dc=com, and add both server accounts. See Section 8.1.3, “Creating Groups in the Command Line”.
    3. Create the replica entry and set the nsds5ReplicaBindDNGroup attribute to the DN of the group created in the previous step:
      # ldapmodify -D "cn=Directory Manager" -W -p 636 -h server1.example.com -x
      
      dn: cn=replica,cn=dc\=example\,dc\=com,cn=mapping tree,cn=config
      changetype: add
      objectclass: top
      objectclass: nsds5replica
      objectclass: extensibleObject
      cn: replica
      nsds5replicaroot: dc=example,dc=com
      nsds5replicaid: 7
      nsds5replicatype: 3
      nsds5flags: 1
      nsds5ReplicaPurgeDelay: 604800
      nsds5replicabinddngroup: cn=repl_server,ou=Groups,dc=example,dc=com
      nsDS5ReplicaBindDNGroupCheckInterval: 0
  3. Initialize the new server:
    1. Create a temporary replication manager account, such as cn=Replication Manager,cn=config, on server2.example.com. See Section 15.4, “Creating the Supplier Bind DN Entry”.
    2. On server1.example.com, create a temporary replication agreement which uses the account from the previous step for authentication:
      # ldapmodify -D "cn=Directory Manager" -W -p 636 -h server1.example.com -x
      
      dn: cn=temporary_agreement,cn=replica,cn=dc\=example\,dc\=com,cn=mapping tree,cn=config
      objectclass: top
      objectclass: nsds5ReplicationAgreement
      cn: temporary_agreement
      nsds5replicahost: server2.example.com
      nsds5replicaport: 636
      nsds5replicabindmethod: SIMPLE
      nsds5ReplicaBindDN: cn=Replication Manager,cn=config
      nsds5replicacredentials: password_of_replication_manager_account
      nsds5replicaroot: dc=example,dc=com
      description: Temporary agreement between server1 and server2
      nsds5replicaupdateschedule: 0000-0500 1
      nsds5replicatedattributelist: (objectclass=*) $ EXCLUDE authorityRevocationList accountUnlockTime memberof
      nsDS5ReplicatedAttributeListTotal: (objectclass=*) $ EXCLUDE accountUnlockTime
      nsds5BeginReplicaRefresh: start
      
      This agreement uses the previously-created replication manager account to initialize the database. Before this initialization, the database on server2.example.com is empty and the accounts with the associated certificates do not exist. Therefore, replication using certificates is not possible before the database is initialized.
  4. After the new server has been initialized:
    1. Remove the temporary replication agreement from server1.example.com:
      # ldapdelete -D "cn=Directory Manager" -W -p 636 -h server1.example.com -x "cn=temporary_agreement,cn=replica,cn=dc\=example\,dc\=com,cn=mapping tree,cn=config"
    2. Remove the temporary replication manager account from server2.example.com:
      # ldapdelete -D "cn=Directory Manager" -W -p 636 -h server2.example.com -x "cn=Replication Manager,cn=config"
  5. Create a replication agreement on both servers that use certificate-based authentication:
    1. On server1.example.com:
      # ldapmodify -D "cn=Directory Manager" -W -p 636 -h server1.example.com -x
      
      dn: cn=example_agreement,cn=replica,cn=dc\=example\,dc\=com,cn=mapping tree,cn=config
      objectclass: top
      objectclass: nsds5ReplicationAgreement
      cn: example_agreement
      nsds5replicahost: server2.example.com
      nsds5replicaport: 636
      nsds5replicabindmethod: SSLCLIENTAUTH
      nsds5replicaroot: dc=example,dc=com
      description: Agreement between server1 and server2
      nsds5replicaupdateschedule: 0000-0500 1
      nsds5replicatedattributelist: (objectclass=*) $ EXCLUDE authorityRevocationList accountUnlockTime memberof
      nsDS5ReplicatedAttributeListTotal: (objectclass=*) $ EXCLUDE accountUnlockTime
      nsDS5ReplicaTransportInfo: SSL
    2. On server2.example.com:
      # ldapmodify -D "cn=Directory Manager" -W -p 636 -h server2.example.com -x
      
      dn: cn=example_agreement,cn=replica,cn=dc\=example\,dc\=com,cn=mapping tree,cn=config
      objectclass: top
      objectclass: nsds5ReplicationAgreement
      cn: example_agreement
      nsds5replicahost: server1.example.com
      nsds5replicaport: 636
      nsds5replicabindmethod: SSLCLIENTAUTH
      nsds5replicaroot: dc=example,dc=com
      description: Agreement between server2 and server1
      nsds5replicaupdateschedule: 0000-0500 1
      nsds5replicatedattributelist: (objectclass=*) $ EXCLUDE authorityRevocationList accountUnlockTime memberof
      nsDS5ReplicatedAttributeListTotal: (objectclass=*) $ EXCLUDE accountUnlockTime
      nsDS5ReplicaTransportInfo: SSL
  6. To verify the replication works correctly, display the nsds5replicaLastUpdateStatus attribute in the replication agreement:
    # ldapsearch -D "cn=Directory Manager" -W -p 636 -h server1.example.com -b "cn=example_agreement,cn=replica,cn=dc\=example\,dc\=com,cn=mapping tree,cn=config" nsds5replicaLastUpdateStatus
    For details about possible statuses, see the Replication Agreement Status appendix in the Red Hat Directory Server Configuration, Command, and File Reference.

15.2.5. Initializing Consumers Online from the Command Line

An online initialization can be initiated from the command line by adding the nsds5replicarefresh attribute to the replication agreement entry. If the attribute is included when the replication agreement is created, initialization begins immediately. It can be added later to initialize the consumer at any time. This attribute is absent by default, and it will be automatically deleted once the consumer initialization is complete.
  1. Find the DN of the replication agreement on the supplier server that is for the consumer to be initialized. For example:
    # ldapsearch -x -h supplier1.example.com -p 389 -D "cn=Directory Manager" -W -s sub -b cn=config "(objectclass=nsds5ReplicationAgreement)"
    This command returns all of the replication agreements configured on the supplier in LDIF format. Get the DN of the replication agreement with the consumer to be initialized. This is the replication agreement which will be edited.
  2. Edit the replication agreement, and add the nsds5BeginReplicaRefresh attribute:
    # ldapmodify -D "cn=Directory Manager" -W -x -h supplier1.example.com
    
    dn: cn=ExampleAgreement,cn=replica,cn=dc\=example\,dc\=com,cn=mapping tree,cn=config
    changetype: modify
    replace: nsds5BeginReplicaRefresh
    nsds5BeginReplicaRefresh: start
    ldapmodify does not prompt for input; simply type in the LDIF statement, and then hit enter twice when the LDIF statement is complete. Close the ldapmodify utility by hitting Ctrl+C.
When the initialization is complete, the nsds5BeginReplicaRefresh attribute is automatically deleted from the replication agreement entry.

Important

For multi-master replication, be sure that consumers are only initialized once, by one supplier. When checking the replication status, be sure to check the replication agreement entry, on the appropriate supplier, which was used to initialize the consumer.
Initializing consumers from the command line is also explained in Section 15.16.3, “Initializing Consumers Online Using the Command Line”. Manually initializing consumers is explained in Section 15.16.4, “Manual Consumer Initialization Using the Command Line”. The replication monitoring attributes are described in more detail in the Red Hat Directory Server Configuration, Command, and File Reference.

Note

For large databases, the nsslapd-idletimeout setting must be set to a large enough time period (or even an unlimited period) to allow the entire database to be initialized before the operation times out. Alternatively, the nsIdleTimeout setting for the supplier bind DN entry can be set high enough to allow the online initialization operation to complete, without having to change the global setting.
To keep data integrity, initialize the consumer databases from the appropriate supplier. Determining the correct supplier can be more difficult in mixed replication environments, but, even when manually initializing consumers, consider four things:
  • Use one supplier, a data master, as the source for initializing consumers.
  • Do not reinitialize a data master when the replication agreements are created. For example, do not initialize server1 from server2 if server2 has already been initialized from server1.
  • For a multi-master scenario, initialize all of the other master servers in the configuration from one master.
  • For cascading replication, initialize all of the hubs from a supplier, then initialize the consumers from the hubs.

15.3. Replication Scenarios

These basic strategies can be combined in a variety of ways to create the best replication environment.

Note

Whatever replication scenario is implemented, consider schema replication. To avoid conflict resolution loops, the Referential Integrity Plug-in should only be enabled on one supplier replica in a multi-master replication environment. The plug-in is off by default.

15.3.1. Single-Master Replication

In the simplest replication scenario, the master copy of directory data is held in a single read-write replica on one server called the supplier server. The supplier server also maintains changelog for this replica. On another server, called the consumer server, there can be multiple read-only replicas. Such scenarios are called single-master configurations. Figure 15.1, “Single-Master Replication” shows an example of single-master replication.
Single-Master Replication

Figure 15.1. Single-Master Replication

In this particular configuration, the ou=people,dc=example,dc=com suffix receives a large number of search requests. Therefore, to distribute the load, this tree, which is mastered on Server A, is replicated to two read-only replicas located on Server B and Server C.
For information on setting up a single-master replication environment, see Section 15.5, “Configuring Single-Master Replication”.

15.3.2. Multi-Master Replication

Directory Server also supports complex replication scenarios in which the same suffix (database) can be mastered on many servers. This suffix is held in a read-write replica on each server. This means that each server maintains a changelog for the read-write replica.
Multi-master replication in Directory Server supports as many as 20 masters, an unlimited number of hub suppliers, and an unlimited number of consumer servers. Each consumer server holds a read-only replica. The consumers can receive updates from any or all the suppliers. The consumers also have referrals defined for all the suppliers to forward any update requests that the consumers receive. Such scenarios are called multi-master configurations.
Figure 15.2, “Multi-Master Replication (Two Masters)” shows an example of multi-master replication scenario with two supplier servers and two consumer servers.
Multi-Master Replication (Two Masters)

Figure 15.2. Multi-Master Replication (Two Masters)

Figure 15.3, “Multi-Master Replication (Four Masters)” shows a sample of multi-master replication scenario with four supplier servers and eight consumer servers. In this sample setup, each supplier server is configured with ten replication agreements to feed data to two other supplier servers and all eight consumer servers. (The Directory Server can have as many as 20 masters in a multi-master setup.)
Multi-Master Replication (Four Masters)

Figure 15.3. Multi-Master Replication (Four Masters)

Multi-master configurations have the following advantages:
  • Automatic write failover when one supplier is inaccessible.
  • Updates are made on a local supplier in a geographically distributed environment.

Note

The speed that replication proceeds depends on:
  • The speed of the network.
  • The number of outgoing and incoming replication agreements. Set up maximum 8 outbound and 4 inbound replication agreements for best performance.
For the procedure to set up multi-master replication, see Section 15.6, “Configuring Multi-Master Replication”.

15.3.3. Cascading Replication

In a cascading replication scenario, one server, a hub, acts both as a consumer and a supplier. It holds a read-only replica and maintains a changelog, so it receives updates from the supplier server that holds the master copy of the data and, in turn, supplies those updates to the consumer. Cascading replication is very useful for balancing heavy traffic loads or to keep master servers based locally in geographically-distributed environments.
Figure 15.4, “Cascading Replication” shows an example of a simple cascading replication scenario, though it is possible to create more complex scenarios with several hub servers.
Cascading Replication

Figure 15.4. Cascading Replication

For information on setting up cascading replication, see Section 15.7, “Configuring Cascading Replication”.

Note

Multi-master and cascading replication can be combined. For example, in the multi-master scenario illustrated in Figure 15.2, “Multi-Master Replication (Two Masters)”, Server C and Server D could be hub servers that would replicate to any number of consumer servers.

15.4. Creating the Supplier Bind DN Entry

A critical part of setting up replication is to create the entry, called the replication manager or supplier bind DN entry, that the suppliers use to bind to the consumer servers to perform replication updates.
The supplier bind DN must meet the following criteria:
  • It must be unique.
  • It must be created on the consumer server (or hub) and not on the supplier server.
  • It must correspond to an actual entry on the consumer server.
  • It must be created on every server that receives updates from another server.
  • It must not be part of the replicated database for security reasons.
  • It must be defined in the replication agreement on the supplier server.
  • It must have an idle timeout period set to a high enough limit to allow the initialization process for large databases to complete. Using the nsIdleTimeOut operational attribute allows the replication manager entry to override the global nsslapd-idletimeout setting.
For example, the entry cn=Replication Manager,cn=config can be created under the cn=config tree on the consumer server. This would be the supplier bind DN that all supplier servers would use to bind to the consumer to perform replication operations.

Note

Avoid creating simple entries under the cn=config entry in the dse.ldif file. The cn=cn=config entry in the simple, flat dse.ldif configuration file is not stored in the same highly scalable database as regular entries. As a result, if many entries, and particularly entries that are likely to be updated frequently, are stored under cn=config, performance will suffer. However, although Red Hat recommends not storing simple user entries under cn=config for performance reasons, it can be useful to store special user entries such as the Directory Manager entry or replication manager (supplier bind DN) entry under cn=config since this centralizes configuration information.
On each server that acts as a consumer in replication agreements, create a special entry that the supplier will use to bind to the consumers. Make sure to create the entry with the attributes required by the authentication method specified in the replication agreement.
  1. Stop the Directory Server. If the server is not stopped, the changes to the dse.ldif file will not be saved. See Section 1.4, “Starting and Stopping a Directory Server Instance” for more information on stopping the server.
  2. Create a new entry, such as cn=replication manager,cn=config, in the dse.ldif file.
  3. Specify a userPassword attribute-value pair.
  4. Set an nsIdleTimeout period that gives the replication user a long enough time limit to allow replication initialization on large databases to complete.
  5. If password expiration policy is enabled or ever will be enabled, disable it on the replication manager entry to prevent replication from failing due to passwords expiring. To disable the password expiration policy on the userPassword attribute, add the passwordExpirationTime attribute with a value of 20380119031407Z, which means that the password will never expire.
  6. Restart the Directory Server. See Section 1.4, “Starting and Stopping a Directory Server Instance” for more information on starting the server.
The final entry should resemble Example 15.4, “Example Supplier Bind DN Entry”.

Example 15.4. Example Supplier Bind DN Entry

dn: cn=replication manager,cn=config
objectClass: top
objectClass: device
objectClass: simpleSecurityObject
cn: replication manager
userPassword: strong_password
nsIdleTimeout: 0
When configuring a replica as a consumer, use the DN of this entry to define the supplier bind DN.

15.5. Configuring Single-Master Replication

To set up single-master replication such as the configuration shown in Figure 15.1, “Single-Master Replication”, between supplier Server A, which holds a read-write replica, and the two consumers Server B and Server C, which each hold a read-only replica, there are three major steps:

15.5.1. Configuring the Read-Write Replica on the Supplier Server

  1. Specify the supplier settings for the server.
    1. In the Directory Server Console, select the Configuration tab.
    2. In the navigation tree, select the Replication folder.
    3. In the right-hand side of the window, select the Supplier Settings tab.
    4. Check the Enable Changelog check box.
      This activates all of the fields in the pane below that were previously grayed out.
    5. Specify a changelog by clicking the Use default button, or click the Browse button to display a file selector.
    6. Set the changelog parameters for the number and age of the log files.
      Clear the unlimited check boxes to specify different values.

      Note

      Red Hat recommends setting the maximum changelog age to 7 days.
    7. Click Save.
  2. Specify the replication settings required for a read-write replica.
    1. In the navigation tree on the Configuration tab, expand the Replication node, and highlight the database to replicate.
      The Replica Settings tab opens in the right-hand side of the window.
    2. Check the Enable Replica check box.
    3. In the Replica Role section, select the Single Master radio button.
    4. In the Common Settings section, specify a Replica ID, which is an integer between 1 and 65534, inclusive.
      The replica ID must be unique for a given suffix, different from any other ID used for read-write replicas on this server and on other servers.
    5. In the Common Settings section, specify a purge delay in the Purge delay field.
      The purge delay is how often the state information stored for the replicated entries is deleted.
    6. Click Save.

15.5.2. Configuring the Read-Only Replica on the Consumer

  1. Create the database for the read-only replica if it does not exist. See Section 2.1.1, “Creating Suffixes” for instructions on creating suffixes.
  2. Create the entry for the supplier bind DN on the consumer server if it does not exist. The supplier bind DN is the special entry that the supplier will use to bind to the consumer. This is described in Section 15.4, “Creating the Supplier Bind DN Entry”.
  3. Specify the replication settings required for a read-only replica.
    1. In the Directory Server Console, select the Configuration tab.
    2. In the navigation tree, expand the Replication folder, and select the replica database.
      If you want to replicate the o=NetscapeRoot database, see Section 15.20, “Replicating o=NetscapeRoot for Administration Server Failover”.
    3. In the Replica Settings tab of the selected database, check the Enable Replica check box.
    4. In the Replica Role section, select the Dedicated Consumer radio button.
    5. In the Common Settings section, specify a purge delay in the Purge delay field.
      This option indicates how often the state information stored for the replicated entries is purged.
    6. In the Update Settings section, specify the bind DN that the supplier will use to bind to the replica. Enter the supplier bind DN in the Enter a new Supplier DN field, and click Add. The supplier bind DN appears in the Current Supplier DNs list.
      The supplier bind DN should be the entry created in step 2. The supplier bind DN is a privileged user because it is not subject to access control.

      Note

      There can be multiple supplier bind DNs per consumer but only one supplier DN per replication agreement.
    7. Specify the URL for any supplier servers to which to refer updates.
      By default, all updates are first referred to the supplier servers that are specified here. If no suppliers are set here, updates are referred to the supplier servers that have a replication agreement that includes the current replica.
      Automatic referrals assume that clients bind over a regular connection; this has a URL in the form ldap://hostname:port. For clients to bind to the supplier using TLS, use this field to specify a referral of the form ldaps://hostname:port, where the s in ldaps indicates a secure connection.

      Note

      It is also possible to use IPv4 or IPv6 addresses instead of the host name.
  4. Click Save.
Repeat these steps for every consumer server in the replication configuration.

15.5.3. Creating the Replication Agreement

On the supplier, create one replication agreement for each read-only replica. For example, in the scenario illustrated in Figure 15.1, “Single-Master Replication”, Server A has two replication agreements, one for Server B and one for Server C.
  1. In the navigation tree of the Configuration tab, right-click the database to replicate, and select New Replication Agreement.
    Alternatively, highlight the database, and select New Replication Agreement from the Object menu to start the Replication Agreement Wizard.
  2. In the first screen, fill in a name and description for the replication agreement, and hit Next.
  3. In the Source and Destination screen, fill in the URL (hostname:port or IP_address:port, with IPv4 or IPv6 addresses) for the consumer and the supplier bind DN and password on that consumer. If the target server is not available, hit in other to fill in the information manually.
    • Unless there is more than one instance of Directory Server configured, by default, there are no consumers available in the drop-down menu.
    • The port listed is the non-TLS port, even if the Directory Server instance is configured to run over TLS. This port number is used only for identification of the Directory Server instance in the Console; it does not specify the actual port number or protocol that is used for replication.
    • If TLS is enabled on the servers, it is possible to select the Using encrypted SSL connection radio button for TLS client authentication. Otherwise, fill in the supplier bind DN and password.

      Note

      If attribute encryption is enabled, a secure connection must be used for the encrypted attributes to be replicated.
  4. Select the connection type. There are three options:
    • Use LDAP. This sets a standard, unencrypted connection.
    • Use TLS/SSL. This uses a secure connection over the server's secure LDAPS port, such as 636. This setting is required to use TLS.
    • Use Start TLS. This uses Start TLS to establish a secure connection over the server's standard port.

    Note

    If secure binds are required for simple password authentication (Section 19.11.1, “Requiring Secure Binds”), then any replication operations will fail unless they occur over a secure connection. Using a secure connection (TLS and Start TLS connections or SASL authentication) is recommended, anyway.
  5. Select the appropriate authentication method and supply the required information. This gives the information that the supplier uses to authenticate and bind to the consumer server to send updates.
    • Simple means that the server connects over the standard port with no encryption. The only required information is the bind DN and password for the Replication Manager (which must exist on the consumer server).
    • Server TLS/SSL Certificate uses the supplier's TLS certificate to authenticate to the consumer server. A certificate must be installed on the supplier for certificate-based authentication, and the consumer server must have certificate mapping configured so that it can map the subject DN in the supplier's certificate to its Replication Manager entry.
      Configuring TLS and certificate mapping is described in Section 9.4, “Enabling TLS”.
    • SASL/DIGEST-MD5, like simple authentication, this insecure method requires only the bind DN and password to authenticate. This can run over a standard or TLS connection.
    • SASL/GSSAPI requires the supplier server to have a Kerberos keytab (as in Section 9.10.2.2, “About the KDC Server and Keytabs”), and the consumer server to have a SASL mapping to map the supplier's principal to the real replication manager entry (as in Section 9.9.3.1, “Configuring SASL Identity Mapping from the Console”).
  6. Fractional replication controls which entry attributes are replicated between servers. By default, all attributes are replicated. To select attributes that will not be replicated to the consumer, check the Enable Fractional Replication check box. Then, highlight the attribute (or attributes) in the Included column on the right, and click Remove. All attributes that will not be replicated are listed in the Excluded column on the left, as well as in the summary the replication agreement is complete.
  7. Set the schedule for when replication runs. By default, replication runs continually.

    Note

    The replication schedule cannot cross midnight (0000). So, it is possible to set a schedule that begins at 0001 and ends at 2359 on the same day, but it is not possible to set one that begins at 2359 on one day and ends at 0001 on the next.
    Hit Next.
  8. Select Initialize consumer now, to start initializing after the replication agreement was completed, and click Next.

    Note

    Replication will not begin until the consumer is initialized.
    For further details on initializing consumers, see Section 15.16, “Initializing Consumers”.
  9. The final screen shows the settings for the replication agreement, as it will be included in the dse.ldif file. Hit Done to save the agreement.
The replication agreement is set up.

Note

After creating a replication agreement, the connection type (TLS or non-TLS) cannot be changed because LDAP and LDAPS connections use different ports. To change the connection type, re-create the replication agreement.

15.6. Configuring Multi-Master Replication

In a multi-master configuration, many suppliers can accept updates, synchronize with each other, and update all consumers. The consumers can send referrals for updates to all masters.
Directory Server supports 20-way multi-master replication, meaning that there can be up to 20 masters (and an unlimited number of hub suppliers) in a single replication scenario. Directory Server allows an unlimited number of consumers.
To set up multi-master replication, set up all of the consumers first, then set up the suppliers, and last, initialize all of the databases.

Note

More than 10 databases running with replication or more than on a supplier can cause performance degradation. To support that many consumers, introduce hub replicas between the suppliers and consumers. See Section 15.7, “Configuring Cascading Replication”.

15.6.1. Configuring the Read-Write Replicas on the Supplier Servers

Set up each supplier server. The first supplier configured should be used to initialize the other suppliers in the multi-master replication environment.
  1. Specify the supplier settings for the server.
    1. In the Directory Server Console, select the Configuration tab.
    2. In the navigation tree, select the Replication folder.
    3. In the right-hand side of the window, select the Supplier Settings tab.
    4. Check the Enable Changelog check box.
      This activates all of the fields in the pane below that were previously grayed out.
    5. Specify a changelog by clicking the Use default button, or click the Browse button to display a file selector.
    6. Set the changelog parameters for the number and age of the log files.
      Clear the unlimited check boxes to specify different values.
    7. Click Save.
  2. Create the entry for the supplier bind DN on the consumer server if it does not exist. This is the special entry that the other suppliers will use to bind to this supplier, as in other supplier-consumer relationships. This is described in Section 15.4, “Creating the Supplier Bind DN Entry”.

    Note

    For multi-master replication, it is necessary to create this supplier bind DN on the supplier servers as well as the consumers because the suppliers act as both consumer and supplier to the other supplier servers.
  3. Specify the replication settings for the multi-mastered read-write replica.
    1. In the Directory Server Console, select the Configuration tab.
    2. In the navigation tree, expand the Replication folder, and highlight the replica database.
      The Replica Settings tab for that database opens in the right-hand side of the window.
    3. Check the Enable Replica check box.
    4. In the Replica Role section, select the Multiple Master radio button.
    5. In the Common Settings section, specify a Replica ID, which is an integer between 1 and 65534, inclusive.
      The replica ID must be unique for a given suffix, different from any other ID used for read-write replicas on this server and on other servers.
    6. In the Common Settings section, specify a purge delay in the Purge delay field.
      The purge delay is how often the state information stored for the replicated entries is deleted.
    7. In the Update Settings section, specify the bind DN that the supplier will use to bind to the replica. Enter the supplier bind DN in the Enter a new Supplier DN field, and click Add. The supplier bind DN appears in the Current Supplier DNs list.
      The supplier bind DN should be the entry created in step 2. The supplier bind DN is a privileged user because it is not subject to access control in the replicated database.

      Note

      There can be multiple supplier bind DNs per consumer but only one supplier DN per replication agreement.
    8. Specify the LDAP URL (ldap://hostname:port or ldap://IP_address:port, with IPv4 or IPv6 addresses) for any supplier servers to which to refer updates, such as the other suppliers in the multi-master replication set. Only specify the URL for the supplier server.
      For clients to bind using TLS, specify a URL beginning with ldaps://.
    9. Click Save.

15.6.2. Configuring the Read-Only Replicas on the Consumer Servers

First, configure every consumer before creating any replication agreements.
  1. Create the database for the read-only replica if it does not exist. See Section 2.1.1, “Creating Suffixes” for instructions on creating suffixes.
  2. Create the entry for the supplier bind DN on the consumer server if it does not exist. The supplier bind DN is the special entry that the supplier will use to bind to the consumer. This is described in Section 15.4, “Creating the Supplier Bind DN Entry”.
  3. Specify the replication settings required for a read-only replica.
    1. In the Directory Server Console, select the Configuration tab.
    2. In the navigation tree, expand the Replication folder, and highlight the replica database.
      The Replica Settings tab for that database opens in the right-hand side of the window.
    3. Check the Enable Replica check box.
    4. In the Replica Role section, select the Dedicated Consumer radio button.
    5. In the Common Settings section, specify a purge delay in the Purge delay field.
      This option indicates how often the state information stored for the replicated entries is purged.
    6. In the Update Settings section, specify the bind DN that the supplier will use to bind to the replica. Enter the supplier bind DN in the Enter a new Supplier DN field, and click Add. The supplier bind DN appears in the Current Supplier DNs list.
      The supplier bind DN should be the entry created in step 2. The supplier bind DN is a privileged user because it is not subject to access control in the replicated database.

      Note

      There can be multiple supplier bind DNs per consumer but only one supplier DN per replication agreement.
    7. Specify the URL for any supplier servers to which to refer updates.
      By default, all updates are first referred to the supplier servers that are specified here. If no suppliers are set here, updates are referred to the supplier servers that have a replication agreement that includes the current replica.
      Automatic referrals assume that clients bind over a regular connection; this has a URL in the form ldap://hostname:port. For clients to bind to the supplier using TLS, use this field to specify a referral of the form ldaps://hostname:port, where the s in ldaps indicates a secure connection.

      Note

      It is also possible to use IPv4 or IPv6 addresses instead of the host name.
  4. Click Save.
Repeat these steps for every consumer server in the replication configuration.

15.6.3. Setting up the Replication Agreements

Note

  1. First set up replication agreements on a single supplier, the data master, between the other multi-master suppliers, and initialize all of the other suppliers.
  2. Then create replication agreements for all other suppliers in the multi-master replication set, but do not reinitialize any of the suppliers.
  3. Then create replication agreements for all of the consumers from the single data master, and initialize the consumers.
  4. Then create replication agreements for all of the consumers from for all of the other suppliers, but do not reinitialize any of the consumers.
  1. In the navigation tree of the Configuration tab, right-click the database to replicate, and select New Replication Agreement.
    Alternatively, highlight the database, and select New Replication Agreement from the Object menu to start the Replication Agreement Wizard.
  2. In the first screen, fill in a name and description for the replication agreement, and hit Next.
  3. In the Source and Destination screen, fill in the URL (hostname:port or IP_address:port, with IPv4 or IPv6 addresses) for the consumer and the supplier bind DN and password on that consumer. If the target server is not available, hit in other to fill in the information manually.
    • Unless there is more than one instance of Directory Server configured, by default, there are no consumers available in the drop-down menu. The server URL can be entered manually, in the format hostname:port or IP_address:port, with IPv4 or IPv6 addresses.
    • The port listed is the non-TLS port, even if the Directory Server instance is configured to run over TLS. This port number is used only for identification of the Directory Server instance in the Console; it does not specify the actual port number or protocol that is used for replication.
    • If TLS is enabled on the servers, it is possible to select the Using encrypted SSL connection radio button for TLS client authentication. Otherwise, fill in the supplier bind DN and password.

      Note

      If attribute encryption is enabled, a secure connection is required for the encrypted attributes to be replicated.
  4. Select the connection type. There are three options:
    • Use LDAP. This sets a standard, unencrypted connection.
    • Use TLS/SSL. This uses a secure connection over the server's secure LDAPS port, such as 636. This setting is required to use TLS.
    • Use Start TLS. This uses Start TLS to establish a secure connection over the server's standard port.

    Note

    If secure binds are required for simple password authentication (Section 19.11.1, “Requiring Secure Binds”), then any replication operations will fail unless they occur over a secure connection. Using a secure connection (TLS and Start TLS connections or SASL authentication) is recommended, anyway.
  5. Select the appropriate authentication method and supply the required information. This gives the information that the supplier uses to authenticate and bind to the consumer server to send updates.
    • Simple means that the server connects over the standard port with no encryption. The only required information is the bind DN and password for the Replication Manager (which must exist on the consumer server).
    • Server TLS/SSL Certificate uses the supplier's TLS certificate to authenticate to the consumer server. A certificate must be installed on the supplier for certificate-based authentication, and the consumer server must have certificate mapping configured so that it can map the subject DN in the supplier's certificate to its Replication Manager entry.
      Configuring TLS and certificate mapping is described in Section 9.4, “Enabling TLS”.
    • SASL/DIGEST-MD5, like simple authentication, requires only the bind DN and password to authenticate. This can run over a standard or TLS connection.
    • SASL/GSSAPI requires the supplier server to have a Kerberos keytab (as in Section 9.10.2.2, “About the KDC Server and Keytabs”), and the consumer server to have a SASL mapping to map the supplier's principal to the real replication manager entry (as in Section 9.9.3.1, “Configuring SASL Identity Mapping from the Console”).
  6. Hit Next.
  7. Fractional replication controls which entry attributes are replicated between servers. By default, all attributes are replicated. To select attributes that will not be replicated to the consumer, check the Enable Fractional Replication check box. Then, highlight the attribute (or attributes) in the Included column on the right, and click Remove. All attributes that will not be replicated are listed in the Excluded column on the left, as well as in the summary the replication agreement is complete.
  8. Set the schedule for when replication runs. By default, replication runs continually.

    Note

    The replication schedule cannot cross midnight (0000). So, it is possible to set a schedule that begins at 0001 and ends at 2359 on the same day, but it is not possible to set one that begins at 2359 on one day and ends at 0001 on the next.
    Hit Next.
  9. Set when the consumer is initialized. Initializing a consumer manually copies all data over from the supplier to the consumer. The default is to create an initialization file (an LDIF of all supplier data) so that the consumer can be initialized later. It is also possible to initialize the consumer as soon as the replication agreement is completed or not at all. For information on initializing consumers, see Section 15.16, “Initializing Consumers”. For multi-master replication, consider the following:
    • Ensure one supplier has the complete set of data to replicate to the other suppliers. Use this one supplier to initialize the replica on all other suppliers in the multi-master replication set.
    • Initialize the replicas on the consumer servers from any of the multi-master suppliers.
    • Do not try to reinitialize the servers when the replication agreements are set up. For example, do not initialize server1 from server2 if server2 has already been initialized from server1. In this case, select Do not initialize consumer.

    Note

    Replication will not begin until the consumer is initialized.

    Important

    For multi-master replication, be sure that consumers are only initialized once, by one supplier. When checking the replication status, be sure to check the replication agreement entry, on the appropriate supplier, which was used to initialize the consumer.
    Hit Next.
  10. The final screen shows the settings for the replication agreement, as it will be included in the dse.ldif file. Hit Done to save the agreement.
The replication agreement is set up.

Note

At the end of this procedure, all supplier servers will have mutual replication agreements, which means that they can accept updates from each other.

Note

After creating a replication agreement, the connection type (TLS or non-TLS) cannot be changed because LDAP and LDAPS connections use different ports. To change the connection type, re-create the replication agreement.

15.6.4. Preventing Monopolization of a Consumer in Multi-Master Replication

One of the features of multi-master replication is that a supplier acquires exclusive access to the consumer for the replicated area. During this time, other suppliers are locked out of direct contact with the consumer. If a supplier attempts to acquire access while locked out, the consumer sends back a busy response, and the supplier sleeps for several seconds before making another attempt. During a low update load, the supplier sends its update to another consumer while the first consumer is locked and then send updates when the first consumer is free again.
A problem can arise if the locking supplier is under a heavy update load or has a lot of pending updates in the changelog. If the locking supplier finishes sending updates and then has more pending changes to send, it will immediately attempt to reacquire the consumer and will most likely succeed, since the other suppliers usually will be sleeping. This can cause a single supplier to monopolize a consumer for several hours or longer.
The following attributes address this issue:
nsds5ReplicaBusyWaitTime
Sets the time in seconds a supplier waits after a consumer sends back a busy response before making another attempt to acquire access.
For example, to configure that a supplier waits 5 seconds before making another acquire attempt:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: cn=Replication_Agreement_Name,cn=replica,cn=suffix_Name,cn=mapping tree,cn=config
changetype: modify
replace: nsds5ReplicaBusyWaitTime
nsds5ReplicaBusyWaitTime: 5
nsds5ReplicaSessionPauseTime
Sets the time in seconds a supplier waits between two update sessions. If you set a value lower or equal than the value specified in nsds5ReplicaBusyWaitTime, Directory Server automatically uses a value for the nsds5ReplicaSessionPauseTime parameter, that is one second higher than the value set in nsds5ReplicaBusyWaitTime.
For example, to configure that the supplier waits 10 seconds between two update sessions:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: cn=Replication_Agreement_Name,cn=replica,cn=suffix_Name,cn=mapping tree,cn=config
changetype: modify
replace: nsds5ReplicaSessionPauseTime
nsds5ReplicaSessionPauseTime: 10
nsds5ReplicaReleaseTimeout
Sets the timeout after which a master will release the replica, whether or not it has finished sending its updates. This prevents a single master from monopolizing a replica.
For example, to configure in a heavy replication environment that a master will release a replica after 90 seconds:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: cn=replica,cn=suffix_Name,cn=mapping tree,cn=config
changetype: modify
replace: nsds5ReplicaReleaseTimeout
nsds5ReplicaReleaseTimeout: 90
For further details, see the parameter descriptions in the Red Hat Directory Server Configuration, Command, and File Reference.
To log replica busy errors, enable Replication error logging (log level 8192). See Section 20.3.7, “Configuring Log Levels”.

15.7. Configuring Cascading Replication

Setting up cascading replication, as shown in Figure 15.4, “Cascading Replication”, has three major steps, for each server in the scenario, the supplier on Server A, which holds a read-write replica; the consumer/supplier on hub Server B, which holds a read-only replica; and the consumer on Server C, which holds a read-only replica:

15.7.1. Configuring the Read-Write Replica on the Supplier Server

Next, configure the supplier server, which holds the original copy of the database:
  1. Specify the supplier settings for the server.
    1. In the Directory Server Console, select the Configuration tab.
    2. In the navigation tree, select the Replication folder.
    3. In the right-hand side of the window, select the Supplier Settings tab.
    4. Check the Enable Changelog check box.
      This activates all of the fields in the pane below that were previously grayed out.
    5. Specify a changelog by clicking the Use default button, or click the Browse button to display a file selector.
    6. Set the changelog parameters for the number and age of the log files.
      Clear the unlimited check boxes to specify different values.
    7. Click Save.
  2. Specify the replication settings required for a read-write replica.
    1. In the navigation tree on the Configuration tab, expand the Replication node, and highlight the database to replicate.
      The Replica Settings tab opens in the right-hand side of the window.
    2. Check the Enable Replica check box.
    3. In the Replica Role section, select the Single Master radio button.
    4. In the Common Settings section, specify a Replica ID, which is an integer between 1 and 65534, inclusive.
      The replica ID must be unique for a given suffix, different from any other ID used for read-write replicas on this server and on other servers.
    5. In the Common Settings section, specify a purge delay in the Purge delay field.
      The purge delay is how often the state information stored for the replicated entries is deleted.
    6. Click Save.
After setting up the supplier replica, begin configuring the replication agreements.

15.7.2. Configuring the Read-Only Replica on the Consumer Server

  1. Create the database for the read-only replica if it does not exist. See Section 2.1.1, “Creating Suffixes” for instructions on creating suffixes.
  2. Create the entry for the supplier bind DN on the consumer server if it does not exist. The supplier bind DN is the special entry that the supplier will use to bind to the consumer. This is described in Section 15.4, “Creating the Supplier Bind DN Entry”.
  3. Specify the replication settings required for a read-only replica.
    1. In the Directory Server Console, select the Configuration tab.
    2. In the navigation tree, expand the Replication folder, and highlight the replica database.
      The Replica Settings tab for that database opens in the right-hand side of the window.
    3. Check the Enable Replica check box.
    4. In the Replica Role section, select the Dedicated Consumer radio button.
    5. In the Common Settings section, specify a purge delay in the Purge delay field.
      This option indicates how often the state information stored for the replicated entries is purged.
    6. In the Update Settings section, specify the bind DN that the supplier will use to bind to the replica. Enter the supplier bind DN in the Enter a new Supplier DN field, and click Add. The supplier bind DN appears in the Current Supplier DNs list.
      The supplier bind DN should be the entry created in step 2. The supplier bind DN is a privileged user because it is not subject to access control in the replicated database.

      Note

      There can be multiple supplier bind DNs per consumer but only one supplier DN per replication agreement.
    7. Specify the URL (hostname:port or IP_address:port, with IPv4 or IPv6 addresses) for any supplier servers to which to refer updates.
      By default, all updates are first referred to the supplier servers that are specified here. If no suppliers are set here, updates are referred to the supplier servers that have a replication agreement that includes the current replica.
      In cascading replication, referrals are automatically sent to the hub server, which in turn refers the request to the original supplier. Therefore, set a referral to the original supplier to replace the automatically generated referral.
  4. Click Save.
Repeat these steps for every consumer server in the replication configuration, then configure the hub replica.

15.7.3. Configuring the Read-Only Replica on the Hub

Do this to set up a hub, which receives replication updates from the supplier and propagates them to consumers:
  1. Create the database for the read-only replica if it does not exist. See Section 2.1.1, “Creating Suffixes” for instructions on creating suffixes.
  2. Create the entry for the supplier bind DN on the consumer server if it does not exist. The supplier bind DN is the special entry that the supplier will use to bind to the consumer. This is described in Section 15.4, “Creating the Supplier Bind DN Entry”.
  3. Create the changelog for the hub server.
    The hub must maintain a changelog even though it does not accept update operations because it records the changes sent from the supplier server.
    1. In the Directory Server Console, select the Configuration tab.
    2. In the navigation tree, select the Replication folder.
    3. In the right-hand side of the window, select the Supplier Settings tab.
    4. Check the Enable Changelog check box.
      This activates all of the fields in the pane below that were previously grayed out.
    5. Specify a changelog by clicking the Use default button, or click the Browse button to display a file selector.
    6. Set the changelog parameters for the number and age of the log files.
      Clear the unlimited check boxes to specify different values.
    7. Click Save.
  4. Specify the required hub replica settings.
    1. In the Directory Server Console, select the Configuration tab.
    2. In the navigation tree, expand the Replication folder, and highlight the replica database.
      The Replica Settings tab for that database opens in the right-hand side of the window.
    3. Check the Enable Replica check box.
    4. In the Replica Role section, select the Hub radio button.
    5. In the Common Settings section, specify a purge delay in the Purge delay field.
      This option sets how often the state information stored for the replicated entries is purged.
    6. In the Update Settings section, specify the bind DN that the supplier will use to bind to the replica. Enter the supplier bind DN in the Enter a new Supplier DN field, and click Add. The supplier bind DN appears in the Current Supplier DNs list.
      The supplier bind DN should be the entry created in step 2. The supplier bind DN is a privileged user because it is not subject to access control in the replicated database.

      Note

      There can be multiple supplier bind DNs per consumer but only one supplier DN per replication agreement.
    7. Specify the URL for any supplier servers to which to refer updates.
      By default, all updates are first referred to the supplier servers that are specified here. If no suppliers are set here, updates are referred to the supplier servers that have a replication agreement that includes the current replica.
      Automatic referrals assume that clients bind over a regular connection; this has a URL in the form ldap://hostname:port. For clients to bind to the supplier using TLS, use this field to specify a referral of the form ldaps://hostname:port, where the s in ldaps indicates a secure connection.

      Note

      It is also possible to use IPv4 or IPv6 addresses instead of the host name.
  5. Click Save.
When all the hubs are configured, then configure the supplier replica.

15.7.4. Setting up the Replication Agreements

Cascading replication requires two sets of replication agreements, the first between the supplier and the hub and the second between the hub and the consumer. To set up the replication agreements:
  1. Create the replication agreement on the supplier for the hub, then use the supplier server to initialize the replica on the hub server.
  2. Then create the replication agreement on the hub for each consumer, and initialize the consumer replicas from the hub.
To set up a replication agreement:
  1. In the navigation tree of the Configuration tab, right-click the database to replicate, and select New Replication Agreement.
    Alternatively, highlight the database, and select New Replication Agreement from the Object menu to start the Replication Agreement Wizard.
  2. In the first screen, fill in a name and description for the replication agreement, and hit Next.
  3. In the Source and Destination screen, fill in the URL (hostname:port or IP_address:port, with IPv4 or IPv6 addresses) for the consumer and the supplier bind DN and password on that consumer. If the target server is not available, hit in other to fill in the information manually.
    • Unless there is more than one instance of Directory Server configured, by default, there are no consumers available in the drop-down menu. The server URL can be entered manually as .hostname:port or IP_address:port, with IPv4 or IPv6 addresses.
    • The port listed is the non-TLS port, even if the Directory Server instance is configured to run over TLS. This port number is used only for identification of the Directory Server instance in the Console; it does not specify the actual port number or protocol that is used for replication.
    • If TLS is enabled on the servers, it is possible to select the Using encrypted SSL connection radio button for TLS client authentication. Otherwise, fill in the supplier bind DN and password.

      Note

      If attribute encryption is enabled, a secure connection must be used for the encrypted attributes to be replicated.
  4. Select the connection type. There are three options:
    • Use LDAP. This sets a standard, unencrypted connection.
    • Use TLS/SSL. This uses a secure connection over the server's secure LDAPS port, such as 636. This setting is required to use TLS.
    • Use Start TLS. This uses Start TLS to establish a secure connection over the server's standard port.

    Note

    If secure binds are required for simple password authentication (Section 19.11.1, “Requiring Secure Binds”), then any replication operations will fail unless they occur over a secure connection. Using a secure connection (TLS and Start TLS connections or SASL authentication) is recommended, anyway.
  5. Select the appropriate authentication method and supply the required information. This gives the information that the supplier uses to authenticate and bind to the consumer server to send updates.
    • Simple means that the server connects over the standard port with no encryption. The only required information is the bind DN and password for the Replication Manager (which must exist on the consumer server).
    • Server TLS/SSL Certificate uses the supplier's TLS certificate to authenticate to the consumer server. A certificate must be installed on the supplier for certificate-based authentication, and the consumer server must have certificate mapping configured so that it can map the subject DN in the supplier's certificate to its Replication Manager entry.
      Configuring TSL and certificate mapping is described in Section 9.4, “Enabling TLS”.
    • SASL/DIGEST-MD5, like simple authentication, requires only the bind DN and password to authenticate. This can run over a standard or TLS connection.
    • SASL/GSSAPI requires the supplier server to have a Kerberos keytab (as in Section 9.10.2.2, “About the KDC Server and Keytabs”), and the consumer server to have a SASL mapping to map the supplier's principal to the real replication manager entry (as in Section 9.9.3.1, “Configuring SASL Identity Mapping from the Console”).
  6. Hit Next.
  7. Fractional replication controls which entry attributes are replicated between servers. By default, all attributes are replicated. To select attributes that will not be replicated to the consumer, check the Enable Fractional Replication check box. Then, highlight the attribute (or attributes) in the Included column on the right, and click Remove. All attributes that will not be replicated are listed in the Excluded column on the left, as well as in the summary the replication agreement is complete.
  8. Set the schedule for when replication runs. By default, replication runs continually.

    Note

    The replication schedule cannot cross midnight (0000). So, it is possible to set a schedule that begins at 0001 and ends at 2359 on the same day, but it is not possible to set one that begins at 2359 on one day and ends at 0001 on the next.
    Hit Next.
  9. Set when the consumer is initialized. Initializing a consumer manually copies all data over from the supplier to the consumer. The default is to create an initialization file (an LDIF of all supplier data) so that the consumer can be initialized later. It is also possible to initialize the consumer as soon as the replication agreement is completed or not at all. For information on initializing consumers, see Section 15.16, “Initializing Consumers”. For cascading replication, consider the following:
    • Create the supplier-hub replication agreement on the supplier first, and initialize the hub from the supplier.
    • Create the hub-consumer replication agreements on the hub, and initialize the consumers from the hub.

    Note

    Replication will not begin until the consumer is initialized.

    Important

    For multi-master replication, be sure that consumers are only initialized once, by one supplier. When checking the replication status, be sure to check the replication agreement entry, on the appropriate supplier, which was used to initialize the consumer.
    Hit Next.
  10. The final screen shows the settings for the replication agreement, as it will be included in the dse.ldif file. Hit Done to save the agreement.

Note

After creating a replication agreement, the connection type (TLS or non-TLS) cannot be change because LDAP and LDAPS connections use different ports. To change the connection type, re-create the replication agreement.

15.8. Temporarily Suspending Replication

By default, replication is enabled and active as soon as the replication agreement is created, and replication proceeds on the given schedule. There can be times when it is necessary to suspend replication, such as when a server is taken down for maintenance. An attribute can be added to the replication agreement entry which disables replication.

15.8.1. Disabling Replication

The nsds5ReplicaEnabled attribute on the replication entry sets whether the replication agreement is active. This attribute is missing by default and has a presumed value of on, meaning that replication is enabled.
To stop replication from a supplier, set the nsds5ReplicaEnabled attribute on the supplier to off.
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: cn=ExampleAgreement,cn=replica,cn=dc\=example\,dc\=com,cn=mapping tree,cn=config
changetype: modify
add: nsds5ReplicaEnabled
nsds5ReplicaEnabled: off

15.8.2. Re-enabling Replication

  1. To re-enable replication, set the nsds5ReplicaEnabled attribute on the supplier to on.
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn: cn=ExampleAgreement,cn=replica,cn=dc\=example\,dc\=com,cn=mapping tree,cn=config
    changetype: modify
    replace: nsds5ReplicaEnabled
    nsds5ReplicaEnabled: on
  2. Initiate an update, such as using the replicate_now.sh script as described in Section 15.17.2, “Forcing Replication Updates from the Command Line”.

15.9. Managing Attributes Within Fractional Replication

As Section 15.1.7, “Replicating a Subset of Attributes with Fractional Replication” describes, fractional replication allows administrators to set attributes that are excluded from replication updates. Administrators can do this for a variety of performance reasons — to limit the number of large attributes that are sent over a network or to reduce the number of times that fixup tasks (like memberOf calculations) are run.
The list of attributes to exclude from replication are defined in the nsDS5ReplicatedAttributeList attribute. This attribute is part of the replication agreement and it can be configured in the replication agreement wizard in the Directory Server Console (or through the command line) when the replication agreement is created.
nsDS5ReplicatedAttributeList: (objectclass=*) $ EXCLUDE memberof authorityRevocationList accountUnlockTime

15.9.1. Setting Different Fractional Replication Attributes for Total and Incremental Updates

When fractional replication is first configured, the list of excluded attributes applies to every update operation. Meaning, this list of attributes is excluded for a total update as well as regular incremental updates. However, there can be times when attributes should be excluded from incremental updates for performance but should be included in a total update to ensure the directory data sets are complete. In this case, it is possible to add a second attribute that defines a separate list of attributes to exclude from total updates, nsDS5ReplicatedAttributeListTotal.

Note

nsDS5ReplicatedAttributeList is the primary fractional replication attribute. If only nsDS5ReplicatedAttributeList is set, then it applies to both incremental updates and total updates. If both nsDS5ReplicatedAttributeList and nsDS5ReplicatedAttributeListTotal are set, then nsDS5ReplicatedAttributeList only applies to incremental updates.
For example, every time a memberOf attribute is added to an entry, a memberOf fixup task is run to resolve the group membership. This can cause overhead on the server if that task is run every time replication occurs. Since a total update only occurs for a database which is newly-added to replication or that has been offline for a long time, running a memberOf fixup task after a total update is an acceptable option. In this case, the nsDS5ReplicatedAttributeList attribute lists memberOf so it is excluded from incremental updates, but nsDS5ReplicatedAttributeListTotal does not list memberOf so that it is included in total updates.
The exclusion list for incremental updates is set in the nsDS5ReplicatedAttributeList attribute for the replication agreement.
nsds5replicatedattributelist: (objectclass=*) $ EXCLUDE authorityRevocationList accountUnlockTime memberof
If nsDS5ReplicatedAttributeList is the only attribute set, then that list applies to both incremental and total updates. To set a separate list for total updates, add the nsDS5ReplicatedAttributeListTotal attribute to the replication agreement.
# ldapmodify -D "cn=Directory Manager" -W -x -D "cn=directory manager" -W -p 389 -h server.example.com -x

dn: cn=ExampleAgreement,cn=replica,cn=dc\=example\,dc\=com,cn=mapping tree,cn=config
changetype: modify
add: nsDS5ReplicatedAttributeListTotal
nsDS5ReplicatedAttributeListTotal: (objectclass=*) $ EXCLUDE accountUnlockTime

Note

The nsDS5ReplicatedAttributeList attribute must be set for incremental updates before nsDS5ReplicatedAttributeListTotal can be set for total updates.

15.9.2. Preventing "Empty" Updates from Fractional Replication

Fractional replication allows a list of attributes which are removed from replication updates (nsDS5ReplicatedAttributeList). However, a changed to an excluded attribute still triggers a modify event and generates an empty replication update.
The nsds5ReplicaStripAttrs attribute adds a list of attributes which cannot be sent in an empty replication event and are stripped from the update sequence. This logically includes operational attribtes like modifiersName.
For example, let's say that the accountUnlockTime attribute is excluded. John Smith's user account is locked and then the time period expires and it is automatically unlocked. Only the accountUnlockTime attribute has changed, and that attribute is excluded from replication. However, the operational attribute internalmodifytimestamp also changed. A replication event is triggered because John Smith's user account was modified — but the only data to send is the new modify time stamp and the update is otherwise emtpy. If there are a large number of attributes related to login times or password expiration times (for example), this could create a flood of empty replication updates that negatively affect server performance or that interfere with associated applications.
To prevent this, add the nsds5ReplicaStripAttrs attribute to the replication agreement to help tune the fractional replication behavior:
# ldapmodify -D "cn=Directory Manager" -W -x -D "cn=directory manager" -W -p 389 -h server.example.com -x

dn: cn=ExampleAgreement,cn=replica,cn=dc\=example\,dc\=com,cn=mapping tree,cn=config
changetype: modify
add: nsds5ReplicaStripAttrs
nsds5ReplicaStripAttrs: modifiersname modifytimestamp internalmodifiersname internalmodifytimestamp
If a replication event is not empty, the stripped attributes are still replicated with the other changes. These attributes are removed from updates only if the event would otherwise be emtpy.

15.10. Making a Read-Only Replica Updatable

Making a read-only server writable means changing the replica from a dedicated consumer or a hub to a supplier.
  1. Make sure there are no updates in progress.
  2. Stop the supplier server.
  3. Enable the change log:
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    dn: cn=changelog5,cn=config
    
    changetype: add
    objectClass: top
    objectClass: extensibleObject
    cn: changelog5
    nsslapd-changelogdir: /var/lib/dirsrv/slapd-instance_name/changelogdb/
  4. Change the replica role:
    • To a single master:
      # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
      dn: cn=replica,cn=dc\3Dexample\2Cdc\3Dcom,cn=mapping tree,cn=config
      changetype: modify
      replace: nsDS5ReplicaType
      nsDS5ReplicaType: 3
      -
      replace: nsDS5Flags
      nsDS5Flags: 1
      -
      replace: nsDS5ReplicaId
      nsDS5ReplicaId: unique_replica_id
      -
      delete: nsDS5ReplicaBindDN
    • To a multi master:
      # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
      dn: cn=replica,cn=dc\3Dexample\2Cdc\3Dcom,cn=mapping tree,cn=config
      changetype: modify
      replace: nsDS5ReplicaType
      nsDS5ReplicaType: 3
      -
      replace: nsDS5Flags
      nsDS5Flags: 1
      -
      replace: nsDS5ReplicaId
      nsDS5ReplicaId: unique_replica_id
      -
      replace: nsDS5ReplicaBindDN
      nsDS5ReplicaBindDN: cn=Replication Manager,cn=config
  5. Stop the Directory Server instance:
    # systemctl stop dirsrv
  6. Back up the /etc/dirsrv/slapd-instance/dse.ldif file:
    # cp /etc/dirsrv/slapd-instance_name/dse.ldif \
         /etc/dirsrv/slapd-instance_name/dse.ldif-1
    Do not name the backup file dse.ldif.bak. Directory Server uses this file name to keep a known working copy of the dse.ldif file.
  7. Edit the /etc/dirsrv/slapd-instance_name/dse.ldif file.
    1. Search for replication agreements. For example:
      dn: cn=replica,cn=dc\5c3Dexample\5c2Cdc\5c3Dcom,cn=mapping tree,cn=config
    2. Remove the line containing the nsState attribute from every replication agreement.
  8. Start the Directory Server instance:
    # systemctl start dirsrv.target
  9. Monitor the error log file for error messages. For details, see Section E.2.3, “Viewing Logs”.
    If the replication fails:
    1. Remove the changelog configuration: Section 15.13, “Removing the Changelog”.
    2. Restart the Directory Server and Admin Console:
      # systemctl restart dirsrv.target
      # systemctl restart dirsrv-admin.service
    3. Create replication agreements: Section 15.3, “Replication Scenarios”.

15.11. Removing a Supplier from the Replication Topology

Removing a supplier cleanly from the replication topology is more complex than simply removing the supplier entry. This is because every supplier in the topology stores information about other suppliers, and they retain that information even if a supplier suddenly becomes unavailable.
Information about the replication topology, that is all suppliers which supply updates to each other and other replicas within the same replication group, is contained in a set of metadata called the replica update vector (RUV). The RUV contains information about the supplier such as its ID and URL, its latest change state number (CSN) on the local server, and the CSN of the first change. Both suppliers and consumers store RUV information, and they use it to control replication updates.
To remove a supplier cleanly, its metadata must be removed along with the configuration entries.
  1. On the replica to remove, put the database into read-only mode to prevent any updates.
    # ldapmodify -D "cn=Directory Manager" -W -x -p 389 -h dead-replica.example.com
    
    dn: cn=userRoot,cn=ldbm database,cn=plugins,cn=config
    changetype: modify
    replace: nsslapd-readonly
    nsslapd-readonly: on
    Allow a few minutes for the replica to flush all of its pending changes.
  2. On all other suppliers in the topology, delete the replication agreement with the replica to be removed.
    # ldapmodify -D "cn=Directory Manager" -W -x -p 389 -h replica1.example.com
    
    dn: cn=Agmt_with_dead-replica,cn=replica,cn=dc\3Dexample\2Cdc\3Dcom,cn=mapping tree,cn=config
    changetype: delete
  3. On the replica to remove, get the replica ID for the replica to remove. This is in the nsds5replicaid attribute in the configuration entry.
    # ldapsearch -xLLL -D "cn=Directory Manager" -W -s sub -b cn=config objectclass=nsds5replica nsds5replicaid
    
    dn: cn=dead-replica,cn=dc\3Dexample\2Cdc\3Dcom,cn=mapping tree,cn=config
    nsds5replicaid: 55
    ...
  4. On the replica to remove, remove all replication agreement entries and its own configuration entry.
    # ldapmodify -D "cn=Directory Manager" -W -x -p 389 -h dead-replica.example.com
    
    dn: cn=to_replica1,cn=dead-replica,cn=dc\3Dexample\2Cdc\3Dcom,cn=mapping tree,cn=config
    changetype: delete
    ...
    
    dn: cn=to_replica2,cn=dead-replica,cn=dc\3Dexample\2Cdc\3Dcom,cn=mapping tree,cn=config
    changetype: delete
    
    dn: cn=dead-replica,cn=dc\3Dexample\2Cdc\3Dcom,cn=mapping tree,cn=config
    changetype: delete
  5. On one of the other master servers in the topology, run the clean command on the replica ID:
    # ldapmodify -a -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn: cn=clean 55, cn=cleanallruv, cn=tasks, cn=config
    objectclass: extensibleObject
    replica-base-dn: dc=example,dc=com
    replica-id: 55
    cn: clean 55
    It is possible to monitor the progress of the task on the other replicas by searching on the tombstone entry on each replica:
    # ldapsearch -xLLL -D "cn=Directory Manager" -W -h remaining-replica.example.com -b "dc=example,dc=com" '(&(nsuniqueid=ffffffff-ffffffff-ffffffff-ffffffff)(objectclass=nstombstone))' nsds50ruv

15.12. Managing Deleted Entries with Replication

When an entry is deleted, it is not immediately removed from the database. Rather, it is converted into a tombstone entry, a kind of backup entry that is used by servers in replication to resolve conflicts. The tombstone entry preserves state information about the original entry.
If there is ever a replication conflict, then the supplier uses the replica ID (the server where the change was initiated) and the timestamp of the change in the change sequence number to resolve the conflict. The oldest change wins. As with deleted entries, deleted attributes are also kept in tombstone entries.
Tombstones are not preserved indefinitely. A purge job is run periodically, at a specified interval (set in the nsDS5ReplicaTombstonePurgeInterval attribute); the purge removes old tombstone entries. Tombstone entries are saved for a given amount of time (set in the nsDS5ReplicaPurgeDelay attribute); once a tombstone entry is older than the delay period, it is reaped at the next purge job.
Both the purge delay and the purge interval are set on the replica entry for a supplier server in the cn=replica,cn=replicated suffix,cn=mapping tree,cn=config configuration entry. There are two considerations when defining the purge settings for replication:
  • The purge operation is time-consuming, especially if the server handles a lot of delete operations. Do not set the purge interval too low or it could consume too many server resources and affect performance.
  • Suppliers use change information, including tombstone entries, to prime replication after initialization. There should be enough of a backlog of changes to effectively re-initialize consumers and to resolve replication conflicts. Do not set the purge delay (the age of tombstone entries) too low or you could lose information required to resolve replication conflicts.
    Set the purge delay so that it is slightly longer than the longest replication schedule in the replication topology. For example, if the longest replication interval is 24 hours, keep tombstone entries around for 25 hours. This ensures that there is enough change history to initialize consumers and prevent the data stored in different suppliers from diverging.
To change the purge settings:
# ldapmodify -D "cn=Directory Manager" -W -x  -h supplier1.example.com

dn: cn=replica,cn=dc\=example\,dc\=com,cn=mapping tree,cn=config
changetype: modify
replace: nsDS5ReplicaTombstonePurgeInterval
nsDS5ReplicaTombstonePurgeInterval: 43200 # in seconds, 12 hours
-
changetype: modify
replace: nsDS5ReplicaPurgeDelay
nsDS5ReplicaPurgeDelay: 90000 # in seconds, 25 hours

Note

To clean up the tombstone entries and the state information immediately, set a very small value to the nsDS5ReplicaTombstonePurgeInterval and nsDS5ReplicaPurgeDelay attributes. Both attributes have values set in seconds, so the purge operations can be initiated almost immediately.

Warning

Always use the purge intervals to clean out tombstone entries from the changelog. Never delete tombstone entries manually.

15.13. Removing the Changelog

The changelog is a record of all modifications on a given replica that the supplier uses to replay these modifications to replicas on consumer servers (or suppliers in the case of multi-master replication).
If a supplier server goes offline, it is important to be able to delete the changelog because it no longer holds a true record of all modifications and, as a result, should not be used as a basis for replication. A changelog can be effectively deleted by deleting the log file.

15.13.1. Removing the Changelog using the Command Line

To remove the changelog from the supplier server:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: cn=changelog5,cn=config
changetype: delete
Directory Server automatically removes the content in the changelog directory after you removed the cn=changelog5,cn=config entry.

15.13.2. Removing the Changelog using the Console

To remove the changelog from the supplier server:
  1. In the Directory Server Console, select the Configuration tab.
  2. Select the Replication folder in the left navigation tree and then the Supplier Server Settings tab in the right pane.
  3. Clear the Enable Changelog check box.
  4. Click Save.
  5. Reinitialize the consumers. See Section 15.16, “Initializing Consumers”.

15.14. Moving the Replication Changelog Directory

In certain situations, you might want to change the Directory Server replication changelog directory. For example, to change the directory to /var/lib/dirsrv/slapd-instance_name/new_changelogdb/:
  1. Display the current directory:
    # ldapsearch -D "cn=Directory Manager" -W -p 389 -h server.example.com -x \
         -b "cn=changelog5,cn=config" nsslapd-changelogdir
    ...
    nsslapd-changelogdir: /var/lib/dirsrv/slapd-instance_name/changelogdb/
    You need the displayed path in a later step to move the directory.
  2. Set the new path:
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn: cn=changelog5,cn=config
    changetype: modify
    replace: nsslapd-changelogdir
    nsslapd-changelogdir: /var/lib/dirsrv/slapd-instance_name/new_changelogdb/
  3. Stop the Directory Server instance:
    # systemctl stop dirsrv@instance_name
  4. Move the content of the previous directory to /var/lib/dirsrv/slapd-instance_name/new_changelogdb/:
    # mv /var/lib/dirsrv/slapd-instance_name/changelogdb/ \
         /var/lib/dirsrv/slapd-instance_name/new_changelogdb/
  5. Delete the previous directory:
    # rm /var/lib/dirsrv/slapd-instance_name/changelogdb/
  6. Start the Directory Server instance:
    # systemctl start dirsrv@instance_name

15.15. Trimming the Replication Changelog

The Directory Server changelog manages a list of received and processed changes. It includes changes of clients ran on the server and additionally directory changes from other replication partners. Using the default settings, Directory Server does not automatically remove entries and the changelog grows infinitely. To control which entries are removed, use the following parameters:
  • nsslapd-changelogmaxage (recommended): Removes entries if they exceed the time set in this parameter.
  • nsslapd-changelogmaxentries: Removes the oldest entries if the total number of records exceed the value set in this parameter.
Any record and all subsequently created records remains in the changelog until it is successfully replicated to all servers in the topology. For example, this occurs in a situation when a Directory Server master was removed from the topology, but the replica update vector (RUV) had not been removed.

15.15.1. Enabling Replication Changelog Trimming

To enable replication changelog trimming and automatically remove entries that are older than 7 days (7d):
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: cn=changelog5,cn=config
changetype: modify
replace: nsslapd-changelogmaxage
nsslapd-changelogmaxage: 7d

Note

Red Hat recommends setting a maximum age in nsslapd-changelogmaxage instead of a maximum number of entries in nsslapd-changelogmaxentries. The time set in nsslapd-changelogmaxage should match the replication purge delay set in nsDS5ReplicaPurgeDelay. For details about nsDS5ReplicaPurgeDelay, see the parameter description in the Red Hat Directory Server Configuration, Command, and File Reference.

15.15.2. Manually Reducing the Size of a Large Changelog

When trimming the replication changelog was not enabled and the database grew to a large size, reduce the changelog size manually in the short term:
  1. To be able to reset the parameters after reducing the changelog size, display the current values of corresponding parameters. For example:
    # ldapsearch -x -D 'cn=Directory Manager' -W -b "cn=changelog5,cn=config" \
         nsslapd-changelogmaxage nsslapd-changelogcompactdb-interval \
         nsslapd-changelogtrim-interval nsslapd-changelogmaxage
    
    dn: cn=changelog5,cn=config
    nsslapd-changelogmaxage: 7d
    nsslapd-changelogcompactdb-interval: 2592000
    nsslapd-changelogtrim-interval: 300
    Parameters that are not displayed in the output are not set and Directory Server uses their default values. For the default values, see the parameter descriptions in the Red Hat Directory Server Configuration, Command, and File Reference.
  2. Reduce the following parameter's value temporarily:
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn: cn=changelog5,cn=config
    changetype: modify
    replace: nsslapd-changelogmaxage
    nsslapd-changelogmaxage: 3d
    -
    replace: nsslapd-changelogtrim-interval
    nsslapd-changelogtrim-interval: 30
    -
    replace: nsslapd-changelogcompactdb-interval
    nsslapd-changelogcompactdb-interval: 300
    Using these settings, Directory Server removes changelog entries older than 3 days (nsslapd-changelogmaxage) within the next 30 seconds (nsslapd-changelogtrim-interval).
  3. Restart the Directory Server instance so that the new value of the nsslapd-changelogcompactdb-interval parameter takes effect:
    # systemctl restart dirsrv@instance
    After the next database update, the database is automatically compacted within the time interval set in the nsslapd-changelogcompactdb-interval parameter.
  4. Reset the updated parameters to their previous values. For example:
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn: cn=changelog5,cn=config
    changetype: modify
    replace: nsslapd-changelogmaxage
    nsslapd-changelogmaxage: 7d
    -
    replace: nsslapd-changelogtrim-interval
    nsslapd-changelogtrim-interval: 300
    -
    replace: nsslapd-changelogcompactdb-interval
    nsslapd-changelogcompactdb-interval: 2592000

    Important

    For performance reasons, do not permanently use too short interval settings.
  5. Restart the Directory Server instance:
    # systemctl restart dirsrv@instance

15.16. Initializing Consumers

Once a replication agreement is created, the consumer must be initialized; that is, the data must be physically copied from the supplier server to the consumer servers.

Note

Replication will not begin until the consumer is initialized.

Note

For large databases, the nsslapd-idletimeout setting must be set to a large enough time period (or even an unlimited period) to allow the entire database to be initialized before the operation times out. Alternatively, the nsIdleTimeout setting for the supplier bind DN entry can be set high enough to allow the online initialization operation to complete, without having to change the global setting.

15.16.1. When to Initialize a Consumer

Consumer initialization involves copying data from the supplier server to the consumer server. Once the subtree has been physically placed on the consumer, the supplier server can begin replaying update operations to the consumer server.
Under normal operations, the consumer should not ever have to be reinitialized. However, any time there is a chance that there is a big discrepancy between the supplier's data and the consumer's, reinitialize the consumer. For example, if the data on the supplier server is restored from backup, then all consumers supplied by that server should be reinitialize. As another example, if the supplier has not been able to contact the consumer for a long time, like a week, the supplier may determine that the consumer is too far out of date to be updated, and must be reinitialized.
The consumer can either be initialized online using the Console or manually using the command line. Online consumer initialization using the Console is an effective method of initializing a small number of consumers. However, since each replica is initialized in sequence, this method is not suited to initializing a large number of replicas. Online consumer initialization is the method to use when the consumer is initialized as part of configuring the replication agreement on the supplier server.
Manual consumer initialization using the command line is a more effective method of initializing a large number of consumers from a single LDIF file.

15.16.2. Online Consumer Initialization Using the Console

Online consumer initialization using the Console is the easiest way to initialize or reinitialize a consumer. However, for replicating across a slow link, this process can be very time-consuming, and manual consumer initialization using the command line may be a more efficient approach. This is described in more detail Section 15.16.4, “Manual Consumer Initialization Using the Command Line”.

Note

When a consumer server is being initialized using the online consumer creation method, all operations (including searches) on the replica are referred to the supplier server until the initialization process is completed.
To initialize or reinitialize a consumer online:
  1. Create a replication agreement.
  2. On the supplier server, on the Directory Server Console, select the Configuration tab.
  3. Expand the Replication folder, then expand the replicated database. Right-click the replication agreement, and choose Initialize Consumer from the pop-up menu.
    A message opens warning that any information already stored in the replica on the consumer will be removed.
  4. Click Yes in the confirmation box.
Online consumer initialization begins immediately. To check the status of the online consumer initialization, open the Summary tab in the Status box. If online consumer initialization is in progress, the status shows that a replica is being initialized.

Important

For multi-master replication, be sure that consumers are only initialized once, by one supplier. When checking the replication status, be sure to check the replication agreement entry, on the appropriate supplier, which was used to initialize the consumer.
To update this window, right-click the replicated database icon in the navigation tree, and choose Refresh Replication Agreements. When online consumer initialization finishes, the status changes to reflect this.
For more information about monitoring replication and initialization status, see Section 15.22, “Monitoring Replication Status”.

15.16.3. Initializing Consumers Online Using the Command Line

Online consumer initialization can be performed through the command line by adding the nsds5BeginReplicaRefresh attribute to the replication agreement entry. This attribute is absent by default, and it will be automatically deleted once the consumer initialization is complete.
  1. Find the DN of the replication agreement on the supplier server that is for the consumer to be initialized. For example:
    # ldapsearch -h supplier1.example.com -p 389 -D "cn=Directory Manager" -W -s sub
         -b cn=config "(objectclass=nsds5ReplicationAgreement)"
    This command returns all of the replication agreements configured on the supplier in LDIF format. Get the DN of the replication agreement with the consumer to be initialized. This is the replication agreement which will be edited.
  2. Edit the replication agreement, and add the nsds5BeginReplicaRefresh attribute:
    # ldapmodify -D "cn=Directory Manager" -W -x -h supplier1.example.com
    
    dn: cn=ExampleAgreement,cn=replica,cn=dc\=example\,dc\=com,cn=mapping tree,cn=config
    changetype: modify
    replace: nsds5BeginReplicaRefresh
    nsds5BeginReplicaRefresh: start
    ldapmodify does not prompt for input; simply type in the LDIF statement, and then hit enter twice when the LDIF statement is complete. Close the ldapmodify utility by hitting Ctrl+C.
To check the initialization status, do an ldapsearch for the replication agreement entry.
# ldapsearch -D "cn=Directory Manager" -W -p 389 -h server.example.com -x -s base -b 'cn=ExampleAgreement,cn=dc\=example\,dc\=com,cn=mapping tree,cn=config' '(objectclass=*)'
If the nsds5BeginReplicaRefresh attribute is present, the initialization is still in progress. If the initialization is complete, then the attribute nsds5ReplicaLastInitStatus shows the status. If the initialization was successful, the value of nsds5ReplicaLastInitStatus is Total update succeeded. If the initialization was not successful, this attribute shows information about the error; check the error logs for both the supplier and consumer for additional information.

Important

For multi-master replication, be sure that consumers are only initialized once, by one supplier. When checking the replication status, be sure to check the replication agreement entry, on the appropriate supplier, which was used to initialize the consumer.
The replication monitoring attributes are described in more detail in the Red Hat Directory Server Configuration, Command, and File Reference.

15.16.4. Manual Consumer Initialization Using the Command Line

Manual consumer initialization using the command line is the fastest method of consumer initialization for sites that are replicating very large numbers of entries. However, the manual consumer initialization process is more complex than the online consumer initialization process. Red Hat suggests using the manual process whenever the online process is inappropriate due to performance concerns.
Initializing or reinitializing a server manually has three steps:
  1. Create a replication agreement.
  2. Export the replica on the supplier server to an LDIF file.
  3. Import the LDIF file with the supplier replica contents to the consumer server.

15.16.4.1. Exporting a Replica to LDIF

There are three ways to convert a replica database to LDIF:
  • When creating a replication agreement, by selecting Create consumer initialization file in the Initialize Consumer dialog box of the Replication Agreement Wizard.
  • From the Directory Server Console, by right-clicking the replication agreement under the Replication folder and choosing Create LDIF File from the pop-up menu.
  • From the command line by using the export command, as described in Section 6.2.3, “Exporting a Database to LDIF Using the Command Line”. Exporting to LDIF with any of the command-line tools requires using an option to export the database as a replica; this means that the exported LDIF contains the proper entries to initialize the consumer when the LDIF is imported.
    For the db2ldif and db2ldif.pl scripts, this is the -r option. For example:
    # db2ldif -r -n database1 -a /export/output.ldif
    For the cn=export,cn=tasks,cn=config entry, this is the nsExportReplica attribute.
    #ldapmodify -a -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
     dn: cn=example export,cn=export,cn=tasks,cn=config
     changetype: add
     objectclass: extensibleObject
     cn: example export
     nsInstance: userRoot
     nsFilename: /home/files/example.ldif
     nsExportReplica: true

15.16.4.2. Importing the LDIF File to the Consumer Server

Import the LDIF file which contains the supplier replica contents to the consumer server by using the import features in the Directory Server Console or by using either the ldif2db script or ldif2db.pl script. Both import methods are described in Section 6.1.4, “Importing from the Command Line”.

Note

With the ldif2db.pl script, the LDIF file import operation does not require a server restart. For more information on command-line scripts, see the Red Hat Directory Server Configuration, Command, and File Reference.

15.17. Forcing Replication Updates

When a Directory Server involved in replication is stopped for regular maintenance, it must be updated immediately when it comes back online. In the case of a supplier in a multi-master environment, the directory information needs to be updated by the other supplier in the multi-master set. In other cases, when a hub or a dedicated consumer is taken offline for maintenance, when they come back online, they need to be updated by the supplier server.
Even if the replication agreements are configured to keep the supplier and consumer servers always in sync, it is not sufficient to bring back up-to-date a server that has been offline for over five minutes. The Always Keep in Sync option means that the server generates a replication operation for every update operation it processes. However, if this replication operation cannot be performed because the consumer is offline, the operation times out after 10 minutes.

Note

The procedures described in this section can only be used when replication is already set up and consumers have been initialized.
To ensure that directory information will be synchronized immediately when a server comes back online, use either the Directory Server Console on the supplier server that holds the reference copy of the directory information or a customizable script.

15.17.1. Forcing Replication Updates from the Console

To ensure that replication updates are sent immediately when a consumer or a supplier in a multi-master replication configuration comes back online after a period of time, do the following on the supplier server that holds the most recent version of the directory information:
  1. In the Directory Server Console, click the Configuration tab, expand the Replication folder and database nodes, and select the replication agreement corresponding to the replica to update.
  2. Right click the replication agreement, and choose Send Updates Now from the drop-down list.
This initiates replication toward the server that holds the information that needs to be updated.

15.17.2. Forcing Replication Updates from the Command Line

To force replication updates, perform the following steps on the supplier server:
  1. Temporarily disable the replication agreement:
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    dn: cn=replication_agreement_name,cn=replica,cn=suffix_DN,cn=mapping tree,cn=config
    changetype: modify
    replace: nsds5ReplicaEnabled
    nsds5ReplicaEnabled: off
  2. Re-enable the replication agreement:
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    dn: cn=replication_agreement_name,cn=replica,cn=suffix_DN,cn=mapping tree,cn=config
    changetype: modify
    replace: nsds5ReplicaEnabled
    nsds5ReplicaEnabled: on

15.18. Replication over TLS

For security reasons, the Directory Servers involved in replication should be configured so that all replication operations occur over an TLS connection. To use replication over TLS:
  • Configure both the supplier and consumer servers to use TLS.
  • Configure the consumer server to recognize the supplier server's certificate as the supplier DN. Do this only to use TLS client authentication rather than simple authentication.
These procedures are described in Section 9.4, “Enabling TLS”.
If attribute encryption is enabled, a secure connection is required for replication.

Note

Replication configured over TLS with certificate-based authentication will fail if the supplier's certificate is only capable of behaving as a server certificate, and not also a client during an TLS handshake. Replication with certificate-based authentication uses the Directory Server's server certificate for authentication to the remote server.
If you use certutil to generate the Certificate Signing Request (CSR), pass the --nsCertType=sslClient,sslServer option to the command to set the certificate required type.
When the servers are configured to use TLS, configure an TLS connection for replication in the Replication Agreement Wizard. The Source and Destination sets how to bind between the supplier and the consumer, and this is where TLS is set.
There are two ways to use TLS for replication:
  • Select SSL Client Authentication.
    With TLS client authentication, the supplier and consumer servers use certificates to authenticate to each other.
  • Select Simple Authentication.
    With simple authentication, the supplier and consumer servers use a bind DN and password to authenticate to each other, which are supplied in the Replication Agreement Wizard text fields provided. Simple authentication takes place over a secure channel but without certificates.

    Note

    If secure binds are required for simple password authentication (Section 19.11.1, “Requiring Secure Binds”), then any replication operations will fail unless they occur over a secure connection. Using a secure connection (TLS and Start TLS connections or SASL authentication) is recommended, anyway.
Once a replication agreement is created, the connection type (TLS or non-TLS) cannot be changed in the agreement because LDAP and LDAPS connections use different ports. To change the connection type, re-create the replication agreement.
Also, the port listed for the consumer is the non-TLS port, even if the Directory Server instance is configured to run over TLS. This port number is used only for identification of the Directory Server instance in the Console; it does not specify the actual port number or protocol that is used for replication.

15.19. Setting Replication Timeout Periods

Suppliers must have an exclusive connection to a consumer to send updates to the directory. As mentioned in Section 15.6.4, “Preventing Monopolization of a Consumer in Multi-Master Replication”, it is possible to configure a wait time for suppliers attempting to connect to a consumer, so that the supplier does not hang while the consumer is tied up with another supplier.
It is also possible to set a timeout period for a supplier, so that it does not stay connected to a consumer interminably attempting to send updates over a slow or broken connection.
There are two attributes which set the timeout period:
  • nsDS5ReplicaTimeout sets the number of seconds that the replication operation waits for a response from the consumer before timing out and failing. To set the optimum number, check the access logs to see the average amount of time that the replication process takes, and set the timeout period accordingly.
  • nsDS5DebugReplicaTimeout sets the timeout period for the replication operation when debug logging is enabled. This setting may be appreciably higher than the nsDS5ReplicaTimeout setting because debug logging can slow down directory operations. This attribute can optionally set an error log level where this parameter is applied; the default is replication debugging (8192).

Note

The timeout period is limited to the maximum 32-bit integer in seconds, which translates to 24.8 days.
Both of these attributes are set in the configuration for the replicated suffix. For example, this sets timeout periods for the ou=People suffix:
# ldapmodify -D "cn=Directory Manager" -W -x

dn: cn=replica,cn="ou=People,dc=example,dc=com",cn=mapping tree,cn=config
changetype: modify
add: nsDS5ReplicaTimeout
nsDS5ReplicaTimeout: 600
add: nsDS5DebugReplicaTimeout
nsDS5DebugReplicaTimeout: 6000

15.20. Replicating o=NetscapeRoot for Administration Server Failover

Replication usually occurs between Directory Server user databases to distribute directory data, but it is also possible to use replication to provide failover support for the Administration Server database, o=NetscapeRoot.
  1. Install and configure the first Directory Server instance.
    The setup-ds-admin.pl script has an option, -f, which references an inf. The inf can be used to import LDIF files through the ConfigFile parameter, and the LDIF files can create databases, suffixes, and replication entries. (The inf file is described in more detail in the Red Hat Directory Server Installation Guide.)
    # setup-ds-admin.pl -f /tmp/server1.inf
    To configure the o=NetscapeRoot database on server1 as a multi-master supplier replica, use the following statements in the inf file:
     [slapd]
    ...
     ConfigFile = repluser.ldif Example 15.4, “Example Supplier Bind DN Entry”  
     ConfigFile = changelog.ldif Example 15.1, “Example Changelog Entry”  
     ConfigFile = replica.ldif Example 15.2, “Example Supplier Replica Entry”  
     ConfigFile = replagreement.ldif Example 15.3, “Example Replication Agreement Entry”  
    ...
  2. Install and configure the second Directory Server instance. For the second server, server2.example.com, use the setup-ds.pl command, which installs a Directory Server instance without installing a local Administration Server.
    # setup-ds.pl -f /tmp/server2.inf
    With server2, use the inf file to create and configure a o=NetscapeRoot database on server2 as a multi-master supplier replica:
     [slapd]
    ...
     ConfigFile = netscaperootdb.ldif Section 2.1.1.3, “Creating Root and Sub Suffixes using the Command Line”  
     ConfigFile = repluser.ldif Example 15.4, “Example Supplier Bind DN Entry”   
     ConfigFile = changelog.ldif Example 15.1, “Example Changelog Entry”  
     ConfigFile = replica.ldif Example 15.2, “Example Supplier Replica Entry”  
     ConfigFile = replagreement.ldif Example 15.3, “Example Replication Agreement Entry”  
    ...
  3. Initialize the o=NetscapeRoot database on server2 from server1. Add the nsds5replicarefresh attribute to the replication agreement on server1.
    # ldapmodify -D "cn=Directory Manager" -W -x -h supplier1.example.com
    
    dn: cn=ExampleAgreement1,cn=replica,cn=o=NetscapeRoot,cn=mapping tree,cn=config
    changetype: modify
    replace: nsds5beginreplicarefresh
    nsds5beginreplicarefresh: start
  4. Run the register-ds-admin.pl to create a local Administration Server on server2 and switch the configuration directory for server2 to its own o=NetscapeRoot database from server1.
    # register-ds-admin.pl
  5. Add the following access control instructions (ACI) on server2, to enable members of the Configuration Administrators Group, the server instance entry SIE group, and the admin user, to run on suffixes belonging to server2. For example, to run on the dc=example,dc=com suffix, enter:
    # ldapmodify -D "cn=Directory Manager" -W -x -h server2.example.com
    dn: dc=example,dc=com
    changetype: modify
    add: aci
    aci: (targetattr="*")(version 3.0; acl "Configuration Administrators Group"; 
     allow (all) groupdn="ldap:///cn=Configuration Administrators,ou=Groups,
     ou=TopologyManagement,o=NetscapeRoot";)
    -
    add: aci
    aci: (targetattr="*")(version 3.0; acl "Configuration Administrator";
     allow (all) userdn="ldap:///uid=admin,
     ou=Administrators,ou=TopologyManagement,o=NetscapeRoot";)
    -
    add: aci
    aci: (targetattr = "*")(version 3.0; acl "SIE Group";  allow (all) groupdn =
     "ldap:///cn=slapd-instance,cn=Red Hat Directory Server,cn=Server Group,
     cn=machine_name,ou=example.com,o=NetscapeRoot";)
  6. Disable the PTA Plug-in on server2 so that it does not pass bind operations for the administrative users in its o=NetscapeRoot to server1.

15.21. Using the Retro Changelog Plug-in

The Retro Changelog plug-in configures Directory Server to maintain a changelog that is compatible with the changelog implemented in Directory Server 4.x.

Note

Only enable the Retro Changelog plug-in if you need to maintain a changelog for directory clients that depend on a Directory Server 4.x-style changelog.
To use the retro changelog plug-in, the Directory Server instance must be configured as a single-master replica.
When the Directory Server is configured to maintain a retro changelog, this changelog is stored in a separate database under a special suffix, cn=changelog.
The retro changelog consists of a single level of entries. Each entry in the changelog has the object class changeLogEntry and can include the attributes listed in Table 15.1, “Attributes of a Retro Changelog Entry”.

Table 15.1. Attributes of a Retro Changelog Entry

Attribute Definition
changeNumber This single-valued attribute is always present. It contains an integer which uniquely identifies each change. This number is related to the order in which the change occurred. The higher the number, the later the change.
targetDN This attribute contains the DN of the entry that was affected by the LDAP operation. In the case of a modrdn operation, the targetDN attribute contains the DN of the entry before it was modified or moved.
changetype Specifies the type of LDAP operation. This attribute can have a value of add, delete, modify, or modrdn.
changes For add and modify operations, contains the changes made to the entry in LDIF format.
newrdn In the case of modrdn operations, specifies the new RDN of the entry.
deleteoldrdn In the case of modrdn operations, specifies whether the old RDN was deleted.
newSuperior In the case of modrdn operations, specifies the newSuperior attribute of the entry.
This section contains information on the following retro changelog items:

15.21.1. Enabling the Retro Changelog Plug-in

The retro changelog plug-in configuration information is stored in the cn=Retro Changelog Plugin,cn=plugins,cn=config entry in dse.ldif. To enable the retro changelog plug-in from the command line:
  1. Create an LDIF file that contains the following LDIF update statements:
    dn: cn=Retro Changelog Plugin,cn=plugins,cn=config
    changetype: modify
    replace: nsslapd-pluginEnabled
    nsslapd-pluginEnabled: on
  2. Use the ldapmodify command to import the LDIF file into the directory.
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x -f retro.ldif
  3. Restart the server.
    For information on restarting the server, see Section 1.4, “Starting and Stopping a Directory Server Instance”.
The retro changelog is created in the directory tree under a special suffix, cn=changelog.
The procedure for enabling the retro changelog plug-in from Directory Server Console is the same as for all Directory Server plug-ins. For information, see Section 1.9.2.2, “Enabling Plug-ins in the Directory Server Console”.

15.21.2. Trimming the Retro Changelog

The size of the retro changelog is automatically reduced if you lower the maximum age of records set in the nsslapd-changelogmaxage parameter and the next trim interval, set in nsslapd-changelog-trim-interval, is executed.
For example, to set maximum age of records in the retro changelog to two days:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: cn=Retro Changelog Plugin,cn=plugins,cn=config
changetype: modify
replace: nsslapd-changelogmaxage
nsslapd-changelogmaxage: 2d

15.21.3. Searching and Modifying the Retro Changelog

The changelog supports search operations and is optimized for searches that include filters of the form (&(changeNumber>=X)(changeNumber<=Y)).
As a general rule, do not perform add or modify operations on the retro changelog entries, although entries can be deleted to trim the size of the changelog. Only modify the retro changelog entry to modify the default access control policy.

15.21.4. Retro Changelog and the Access Control Policy

When the retro changelog is created, the following access control rules apply by default:
  • Read, search, and compare rights are granted to all authenticated users (userdn=anyone, not to be confused with anonymous access where userdn=all) to the retro changelog top entry cn=changelog.
  • Write and delete access are not granted, except implicitly to the Directory Manager.
Do not grant read access to anonymous users because the changelog entries can contain modifications to sensitive information, such as passwords. Only authenticated applications and users should be allowed to access this information.
To modify the default access control policy which applies to the retro changelog, modify the aci attribute of the cn=changelog entry.

15.22. Monitoring Replication Status

The replication status can be viewed in the Directory Server Console, Red Hat Administration Express (Section 15.22.2, “Monitoring Replication from Admin Express”), or from the command line.

15.22.1. Monitoring Replication Status from the Console

  1. Select the Status tab, and then, in the left navigation tree, select Replication Status.
    In the right pane, a table appears that contains information about each of the replication agreements configured for this server.
  2. Click Refresh to update the contents of the tab.
    The status information displayed is described in Table 15.2, “Directory Server Console Replication Status”.

Table 15.2. Directory Server Console Replication Status

Table Header Description
Agreement The name of the replication agreement.
Replica suffix The suffix that is replicated.
Supplier The supplier server in the agreement.
Consumer The consumer server in the agreement.
Number of changes A ratio showing the changes sent to this replica since the server started. This value has the format replica_id:changes_sent/changes_skipped. So, if the replica ID is 7, 100 changes were sent, and no changes were skipped, the value of the number of changes is 7:100/0.
Last replica update began The time when the most recent replication update started.
Last replica update ended The time when the most recent replication update ended.
Last update message The status for the most recent replication updates.
Consumer initialization The current status on consumer initialization (in progress or not).
Last consumer initialization update message The status on the last initialization of the consumer.
Last consumer initialization began The time when the initialization of the consumer replica started.
Last consumer initialization ended The time when the initialization of the consumer replica ended.

15.22.2. Monitoring Replication from Admin Express

Admin Express has an option to monitor replication status in real-time, meaning that it shows the number of updates, times the most recent updates were sent, error and success messages, replication schedule, the replicated directory suffix, and other information. Unlike other ways of checking replication status, the Admin Express Replication Status page shows the real-time status of replication, including updates in progress, current changes sequence numbers, and the lag between when a change is made on the supplier and when that change is sent to the consumer.
Monitoring replication is set up using a simple configuration file which specifies which server to monitor and what supplier and consumer replicas to include in the status page.
When trying to monitor replication status through Admin Express, remember two things:
  • The Replication Status page is only available for supplier servers. (It can be opened for other types of replicas; there is just no information available and has the message The server is not a master or it has no replication agreement.)
  • The configuration file must be in a directory that is accessible to Administration Server, and the file must be readable by the Administration Server user. By default, the user is dirsrv.
    The user is set in the console.conf file. To check the user, use grep to return the value:
    # grep \^User /etc/dirsrv/admin-serv/console.conf
    The configuration file should be readable by the Administration Server user and no other users, so consider resetting the permissions on the file:
    # chmod 0400 filename
To view in-progress status of replication in Admin Express:
  1. Create a configuration file. The configuration file lists all of the servers to monitor for replication, giving their host name or IPv4 or IPv6 address, port, the bind credentials to use, and then optional settings for aliases and time lag colors.
    #Configuration File for Monitoring Replication Using Admin Express
    	[connection] Required. Gives the server host (or IPv4 or IPv6 address), port, supplier bind DN, and password.  
    host1.example.com:389:cn=replication manager:mypassword
    host2.example.com:3891:cn=replication manager:altpassword
    
    [alias] Optional. Gives a friendly-name alias to the servers and consumers.  
    M1 = host1.example.com:389
    M2 = host2.example.com:3891
    C1 = host3.example.com:3892
    C2 = host4.example.com:3890
    
    [color] Optional. Sets the color for the time lag boxes.  
    0 = #ccffcc
    5 = #FFFFCC
    60 = #FFCCCC
    The configuration file must be in a directory that is accessible to the Administration Server, and the file must be readable by the Administration Server user. By default, the user is dirsrv.
    The user is set in the console.conf file. To check the user, use grep to return the value:
    # grep \^User /etc/dirsrv/admin-serv/console.conf
    The configuration file should be readable by the Administration Server user and no other users, so consider resetting the permissions on the file:
    # chmod 0400 filename
  2. In the Administration Server web page, click the Admin Express link, and log in.
  3. Click the Replication Status link by the supplier server name.
  4. Type the path to the configuration file in the Configuration file field. Also, set the refresh rate, which is how frequently the replication status page updates; the default is 300 seconds.
    Viewing Replication Status

    Figure 15.5. Viewing Replication Status

  5. Click OK.
The Replication Status page shows the status for sending updates to every consumer listed in the configuration file.
Viewing Replication Status

Figure 15.6. Viewing Replication Status

Table Description
Table header The table header shows the replica ID of the supplier replica, the replicated suffix root (such as dc=example,dc=com), and the maximum change state number (CSN) on the supplier. (The CSN is the ID of the latest change on the supplier, while the max CSN for the supplier shows the last update it received.)
Max CSN The ID number of the most recent CSN the consumer has received that originated from the supplier.
Time lag How long it takes for the consumer to receive updates from the supplier; this is the time difference between the supplier and the consumer's max CSNs. When a consumer is in sync with its supplier, the time lag is 0.
Last Modify Time Gives the time of the last update for the consumer (the time the last CSN entry was sent).
Supplier Gives the name of the supplier sending updates to that consumer; this can be useful if a consumer receives updates from multiple suppliers or there are multiple suppliers being monitored on the Replication Status page.
Sent/Skipped The number of changes that were sent from the supplier and the number skipped in the replication update. The numbers are kept in suppliers' memory only and are cleared if the supplier is restarted.
Update Status The status code (and meaning) for the last update. This column can indicate a possible deadlock if all the suppliers complain that they cannot acquire a busy replica. It is normal for there to be a busy message if one of the suppliers is doing an update.
Update Start and End The timestamps for when the most recent update process started and ended.
Schedule The configured replication schedule. 0:-: means that the consumer is continually updated by the supplier.
SSL? Indicates whether the supplier connects to the consumer over TLS.

15.22.3. Monitoring Replication from the Command-Line

To display replication status from the command line, run the /usr/bin/repl-monitor.pl script with the -s option added. The script prints the report in plain text format and is useful, for example, in situations when the user wants to quickly determine the replication status but a browser is not available. Similarly to Admin Express described in Section 15.22.2, “Monitoring Replication from Admin Express”, repl-monitor.pl shows replication status in real-time.
The repl-monitor.pl script accepts a number of command-line options. For more information on how to use it, see the repl-monitor(1) man page or the Directory Server Configuration, Command, and File Reference guide.

Note

When run without the -s option, repl-monitor.pl generates the report as an HTML file.

15.23. Comparing Two Directory Server Instances

In certain situations, an administrator wants to compare if two Directory Servers are synchronized. The ds-replcheck utility enables you to compare two online servers. Alternatively, ds-replcheck can compare two LDIF-formatted files in offline mode.

Note

To compare two databases offline, export them using the db2ldif -r command to include replication state information.
If you compare two online servers, the contents of the databases usually differ, if they are under heavy load. To work around this problem, the script uses a lag time value in by passing the -l time_in_seconds parameter to ds-replcheck. By default, this value is set to 300 seconds (5 minutes). If the utility detects an inconsistency that is within the lag time, it is not reported. This helps to reduce false positives.
By default, if you excluded certain attributes in the replication agreement from being replicated, ds-replcheck reports these attributes as different. To ignore these attributes, pass the -i attribute_list parameter to the utility.
For example, to compare the dc=example,dc=com suffix of two Directory Servers:
# ds-replcheck -D "cn=Directory Manager" -W \
     -m ldap://server1.example.com:389 \
     -r ldap://server2.example.com:389 \
     -b "dc=example,dc=com"
The output of the utility contains the following sections:
Database RUV's
Lists the Replication Update Vectors (RUV) of the databases including the minimum and maximum Change Sequence Numbers (CSN). For example:
Master RUV:
  {replica 1 ldap://server1.example.com:389} 58e53b92000200010000 58e6ab46000000010000
  {replica 2 ldap://server2.example.com:389} 58e53baa000000020000 58e69d7e000000020000
  {replicageneration} 58e53b7a000000010000

Replica RUV:
  {replica 1 ldap://server1.example.com:389} 58e53ba1000000010000 58e6ab46000000010000
  {replica 2 ldap://server2.example.com:389} 58e53baa000000020000 58e7e8a3000000020000
  {replicageneration} 58e53b7a000000010000
Entry Count
Displays the total number of entries on the both servers, including tombstone entries. For example:
Master:  12
Replica: 10
Tombstones
Displays the number of tombstone entries on each replica. These entries are added to the total entry count. For example:
Master:  4
Replica: 2
Conflict Entries
Lists the Distinguished Names (DN) of each conflict entry, the conflict type, and the date it was created. For example:
Master Conflict Entries: 1

 - nsuniqueid=48177227-2ab611e7-afcb801a-ecef6d49+uid=user1,dc=example,dc=com
    - Conflict:   namingConflict (add) uid=user1,dc=example,dc=com
    - Glue entry: no
    - Created:    Wed Apr 26 20:27:40 2017


Replica Conflict Entries: 1

 - nsuniqueid=48177227-2ab611e7-afcb801a-ecef6d49+uid=user1,dc=example,dc=com
    - Conflict:   namingConflict (add) uid=user1,dc=example,dc=com
    - Glue entry: no
    - Created:    Wed Apr 26 20:27:40 2017
Missing Entries
Lists the DNs of each missing entry and the creation date from the other server where the entry resides. For example:
  Entries missing on Master:
   - uid=user2,dc=example,dc=com (Created on Replica at: Wed Apr 12 14:43:24 2017)
   - uid=user3,dc=example,dc=com (Created on Replica at: Wed Apr 12 14:43:24 2017)

  Entries missing on Replica:
   - uid=user4,dc=example,dc=com (Created on Master at: Wed Apr 12 14:43:24 2017)
Entry Inconsistencies
Lists the DNs of the entry that contain attributes that are different to those on the other server. If a state information is available, it is also displayed. If no state information for an attribute is available, it is listed as an origin value. This means that the value was not updated since the replication was initialized for the first time. For example:
cn=group1,dc=example,dc=com
---------------------------
Replica missing attribute "objectclass":

 - Master's State Info: objectClass;vucsn-58e53baa000000020000: top
 - Date: Wed Apr  5 14:47:06 2017

 - Master's State Info: objectClass;vucsn-58e53baa000000020000: groupofuniquenames
 - Date: Wed Apr  5 14:47:06 2017
For further details about the ds-replcheck utility, see the description in the Red Hat Configuration, Command, and File Reference.

15.24. Solving Common Replication Conflicts

Multi-master replication uses an eventually-consistency replication model. This means that the same entries can be changed on different servers. When replication occurs between these two servers, the conflicting changes need to be resolved. Mostly, resolution occurs automatically, based on the time stamp associated with the change on each server. The most recent change takes precedence.
However, there are some cases where conflicts require manual intervention in order to reach a resolution. Entries with a change conflict that cannot be resolved automatically by the replication process contain the nsds5ReplConflict conflict marker attribute and the ldapSubEntry object class. The nsds5ReplConflict attribute is an operational attribute which is indexed for presence and equality.
To list conflict entries:
# ldapsearch -D "cn=Directory Manager" -W -b "dc=example,dc=com" \
     "(&(objectClass=ldapSubEntry)(nsds5ReplConflict=*))" \* nsds5ReplConflict

15.24.1. Solving Naming Conflicts

When two entries are created with the same DN on different servers, the automatic conflict resolution procedure during replication renames the last entry created, including the entry's unique identifier in the DN. Every directory entry includes a unique identifier stored in the nsuniqueid operational attribute. When a naming conflict occurs, this unique ID is appended to the non-unique DN.
For example, if the uid=user_name,ou=People,dc=example,dc=com entry was created on two different servers, replication adds the unique ID to the DN of the last entry created. This means, the following entries exist:
  • uid=user_name,dc=example,dc=com
  • nsuniqueid=66446001-1dd211b2+uid=user_name,dc=example,dc=com
To resolve the replication conflict, you must manually decide how to proceed:

15.24.1.1. Renaming an Entry with a Multi-Valued Naming Attribute

To rename an entry that has a multi-valued naming attribute:
  1. Rename the entry using a new value for the naming attribute, and keep the old RDN. For example:
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
      dn: nsuniqueid=66446001-1dd211b2+uid=adamss,dc=example,dc=com
      changetype: modrdn
      newrdn: uid=NewValue
      deleteoldrdn: 0
    For further details about keeping an RDN when renaming an entry, see Section 3.1.6.3, “The deleteOldRDN Parameter”.
  2. Remove the old RDN value of the naming attribute and the conflict marker attribute. For example:
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
      dn: uid=NewValue,dc=example,dc=com
      changetype: modify
      delete: uid
      uid: adamss
      -
      delete: nsds5ReplConflict
      -

Note

The unique identifier attribute nsuniqueid cannot be deleted.
The Console does not support editing multi-valued RDNs. For example, if there are two servers in a multi-master mode, an entry can be created on each server with the same user ID, and then the new entries' RDN changed to the nsuniqueid uid value. Attempting to modify this entry from the Console returns the error Changes cannot be saved for entries with multi-valued RDNs.
Opening the entry in the advanced mode shows that the naming attribute has been set to nsuniqueid uid. However, the entry cannot be changed or corrected by changing the user ID and RDN values to something different. For example, if jdoe was the user ID and it should be changed to jdoe1, it cannot be done from the Console. Instead, use the ldapmodify command:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: cn=John Doe
changetype: modify
replace: uid
uid: jdoe

dn: cn=John Doe
changetype: modrdn
newrdn: uid=jdoe1
deleteoldrdn: 1

15.24.1.2. Renaming an Entry with a Single-Valued Naming Attribute

To rename an entry that has a single-valued naming attribute:
  1. Rename the entry using a different naming attribute, and keep the old RDN. For example:
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
      dn: nsuniqueid=66446001-1dd211b2+dc=pubs,dc=example,dc=com
      changetype: modrdn
      newrdn: cn=TempValue
      deleteoldrdn: 0
    For further details about keeping an RDN when renaming an entry, see Section 3.1.6.3, “The deleteOldRDN Parameter”.
  2. Remove the old RDN value of the naming attribute and the conflict marker attribute. For example:
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
      dn: cn=TempValue,dc=example,dc=com
      changetype: modify
      delete: dc
      dc: pubs
      -
      delete: nsds5ReplConflict
      -

    Note

    The unique identifier attribute nsuniqueid cannot be deleted.
  3. Rename the entry with the intended attribute-value pair. For example:
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
      dn: cn=TempValue,dc=example,dc=com
      changetype: modrdn
      newrdn: dc=NewValue
      deleteoldrdn: 1
    Setting the value of the deleteoldrdn attribute to 1 deletes the temporary attribute-value pair cn=TempValue. To keep this attribute, set the value of the deleteoldrdn attribute to 0.

15.24.2. Solving Orphan Entry Conflicts

When a delete operation is replicated and the consumer server finds that the entry to be deleted has child entries, the conflict resolution procedure creates a glue entry to avoid having orphaned entries in the directory.
In the same way, when an add operation is replicated and the consumer server cannot find the parent entry, the conflict resolution procedure creates a glue entry representing the parent so that the new entry is not an orphan entry.
Glue entries are temporary entries that include the object classes glue and extensibleObject. Glue entries can be created in several ways:
  • If the conflict resolution procedure finds a deleted entry with a matching unique identifier, the glue entry is a resurrection of that entry, with the addition of the glue object class and the nsds5ReplConflict attribute.
    In such cases, either modify the glue entry to remove the glue object class and the nsds5ReplConflict attribute to keep the entry as a normal entry or delete the glue entry and its child entries.
  • The server creates a minimalistic entry with the glue and extensibleObject object classes.
In such cases, modify the entry to turn it into a meaningful entry or delete it and all of its child entries.

15.24.3. Resolving Errors for Obsolete or Missing Suppliers

Information about the replication topology, that is all suppliers which supply updates to each other and other replicas within the same replication group, is contained in a set of metadata called the replica update vector (RUV). The RUV contains information about the supplier such as its ID and URL, its latest change state number (CSN) on the local server, and the CSN of the first change. Both suppliers and consumers store RUV information, and they use it to control replication updates.
When one supplier is removed from the replication topology, it may remain in another replica's RUV. When the other replica is restarted, it can record errors in its log, warning that the replication plug-in does not recognize the removed supplier. The errors will look similar to the following example:
[22/Jan/2018:17:16:01 -0500] NSMMReplicationPlugin - ruv_compare_ruv: RUV [changelog max RUV] does not contain element [{replica 8 ldap://m2.example.com:389} 4aac3e59000000080000 4c6f2a02000000080000] which is present in RUV [database RUV]

<...several more samples...>

[22/Jan/2018:17:16:01 -0500] NSMMReplicationPlugin - replica_check_for_data_reload: Warning: for replica dc=example,dc=com there were some differences between the changelog max RUV and the database RUV. If there are obsolete elements in the database RUV, you should remove them using the CLEANALLRUV task. If they are not obsolete, you should check their status to see why there are no changes from those servers in the changelog.
Note which replica and its ID; in this case, replica 8.
When the supplier is permanently removed from the topology, then any lingering metadata about that supplier should be purged from every other supplier's RUV entry. Use the cleanallruv directory tasks to remove a RUV entry from all suppliers in the topology.

Note

The cleanallruv task is replicated. Therefore, you only need to run it on one master.

Procedure 15.1. Removing an Obsolete or Missing Supplier Using the cleanallruv Task Operation

  1. List all RUV records and replica IDs, both valid and invalid, as deleted masters may have left metadata on other masters:
    # ldapsearch -o ldif-wrap=no -xLLL -H m1.example.com -D "cn=Directory Manager" -W -b dc=example,dc=com '(&(nsuniqueid=ffffffff-ffffffff-ffffffff-ffffffff)(objectclass=nstombstone))' nsDS5ReplicaId nsDS5ReplicaType nsds50ruv
    dn: cn=replica,cn=dc\3Dexample\2Cdc\3Dcom,cn=mapping tree,cn=config
    nsDS5ReplicaId: 1
    nsDS5ReplicaType: 3
    nsds50ruv: {replicageneration} 55d5093a000000010000
    nsds50ruv: {replica 1 ldap://m1.example.com:389} 55d57026000000010000 55d57275000000010000
    nsds50ruv: {replica 20 ldap://m2.example.com:389} 55e74b8c000000140000 55e74bf7000000140000
    nsds50ruv: {replica 9 ldap://m2.example.com:389}
    nsds50ruv: {replica 8 ldap://m2.example.com:389} 506f921f000000080000 50774211000500080000
    
    Note the returned replica IDs: 1, 20, 9, and 8.
  2. List the currently defined and valid replica IDs of all masters which are replicating databases by searching the replica configuration entries DN cn=replica under the cn=config suffix.

    Note

    Consumers and read-only nodes always have the replica ID set to 65535, and nsDS5ReplicaType: 3 signifies a master.
    # ldapsearch -o ldif-wrap=no -xLLL -H m1.example.com m2.example.com -D "cn=Directory Manager" -W -b cn=config cn=replica nsDS5ReplicaId nsDS5ReplicaType
    dn: cn=replica,cn=dc\3Dexample\2Cdc\3Dcom,cn=mapping tree,cn=config
    nsDS5ReplicaId: 1
    nsDS5ReplicaType: 3
    
    dn: cn=replica,cn=dc\3Dexample\2Cdc\3Dcom,cn=mapping tree,cn=config
    nsDS5ReplicaId: 20
    nsDS5ReplicaType: 3
    
    After you search all URIs returned in the first step (in this procedure, m1.example.com and m2.example.com), compare the list of returned masters (entries which have nsDS5ReplicaType: 3) to the list of RUVs from the previous step. In the above example, this search only returned IDs 1 and 20, but the previous search also returned 9 and 8 on URI m2.example.com. This means that the latter two are removed, and their RUVs need to be cleaned.
  3. After determining which RUVs require cleaning, create a new cn=cleanallruv,cn=tasks,cn=config entry and provide the following information about your replication configuration:
    • The base DN of the replicated database (replica-base-dn)
    • The replica ID (replica-id)
    • Whether to catch up to the maximum change state number (CSN) from the missing supplier, or whether to just remove all RUV entries and miss any updates (replica-force-cleaning); setting this attribute to no means that the task will wait for all the configured replicas to catch up with all the changes from the removed replica first, and then remove the RUV.
    # ldapmodify -a -D "cn=Directory Manager" -W -H m2.example.com -x
    dn: cn=clean 8,cn=cleanallruv,cn=tasks,cn=config
    objectclass: extensibleObject
    replica-base-dn: dc=example,dc=com
    replica-id: 8
    replica-force-cleaning: no
    cn: clean 8

    Note

    The cleanallruv task is replicated. Therefore, you only need to run it on one master.
    Repeat the same for every RUV you want to clean (ID 9 in this procedure).
  4. After cleaning the RUVs of all replicas discovered earlier, you can again use the search from the first step to verify that all extra RUVs are removed:
    # ldapsearch -o ldif-wrap=no -xLLL -H m1.example.com -D "cn=Directory Manager" -W -b dc=example,dc=com '(&(nsuniqueid=ffffffff-ffffffff-ffffffff-ffffffff)(objectclass=nstombstone))' nsDS5ReplicaId nsDS5ReplicaType nsds50ruv
    dn: cn=replica,cn=dc\3Dexample\2Cdc\3Dcom,cn=mapping tree,cn=config
    nsDS5ReplicaId: 1
    nsDS5ReplicaType: 3
    nsds50ruv: {replicageneration} 55d5093a000000010000
    nsds50ruv: {replica 1 ldap://m1.example.com:389} 55d57026000000010000 55d57275000000010000
    nsds50ruv: {replica 20 ldap://m2.example.com:389} 55e74b8c000000140000 55e74bf7000000140000
    
    As you can see in the above output, replica IDs 8 and 9 are no longer present, which indicates that their RUVs have been cleaned successfully.

Chapter 16. Synchronizing Red Hat Directory Server with Microsoft Active Directory

Windows Synchronization carries over changes in a directory — adds, deletes, and changes in groups, users, and passwords — between Red Hat Directory Server and Microsoft Active Directory. This makes it much more efficient and effective to maintain consistent information across directories.

16.1. About Windows Synchronization

Synchronization allows the user and group entries in Active Directory to be matched with the entries in the Red Hat Directory Server. As entries are created, modified, or deleted, the corresponding change is made to the sync peer server, allowing two-way synchronization of users, passwords, and groups.
The synchronization process is analogous to the replication process: the synchronization is enabled by a plug-in, configured and initiated through a sync agreement, and record of directory changes is maintained and updates are sent according to that changelog. This synchronizes users and groups between Directory Server and a Windows server.
Windows Synchronization has two parts is configured in two parts, one for user and group entries and the other for passwords:
  • Directory Server Windows Synchronization. Synchronization for user and group entries is configured in a synchronization agreement, much like replication is configured in a replication agreement. A sync agreement defines what kinds of entries are synchronized (users, groups, or both) and which direction changes are synced (from the Directory Server to Active Directory, from Active Directory to Directory Server, or both).
    The Directory Server relies on the Multi-Master Replication Plug-in to synchronize user and group entries. The same changelog that is used for multi-master replication is also used to send updates from the Directory Server to Active Directory as LDAP operations. The server also performs LDAP search operations against its Windows server to synchronize changes made to Windows entries to the corresponding Directory Server entry.
  • Password Synchronization Service. Password changes made on Directory Server are automatically synced over to Active Directory, but there must be a special hook to recognize and transmit password changes on Active Directory over to Directory Server. This is done by the Password Synchronization Service. This application captures password changes on the Windows machines and send them to the Directory Server over LDAPS.
    The Password Synchronization Service must be installed on every Active Directory domain controller.
Active Directory — Directory Server Synchronization Process

Figure 16.1. Active Directory — Directory Server Synchronization Process

Synchronization is configured and controlled by one or more synchronization agreements, which establishes synchronization between sync peers, the directory servers being synced. These are similar in purpose to replication agreements and contain a similar set of information, including the host name (or IPv4 or IPv6 address) and port number for Active Directory. The Directory Server connects to its peer Windows server using LDAP/LDAPS to both send and receive updates.
LDAP, a standard connection, can be used for syncing user and group entries alone, but to synchronize passwords, some sort of secure connection is required. If a secure connection is not used, the Windows domain will not accept password changes from the Directory Server and the Password Synchronization Service will not send passwords from the Active Directory domain to the Directory Server. Windows Synchronization allows both LDAPS using TLS and Start TLS.
Multiple subtree pairs can be configured to sync each other. Unlike replication, which connects databases, synchronization is between suffixes, parts of the directory tree structure. The synced Active Directory and Directory Server suffixes are both specified in the sync agreement. All entries within the respective subtrees are candidates for synchronization, including entries that are not immediate children of the specified suffix DN.

Note

Any descendant container entries need to be created separately in Active Directory by an administrator; Windows Synchronization does not create container entries.
The Directory Server maintains a changelog, a database that records modifications that have occurred. The changelog is used by Windows Synchronization to coordinate and send changes made to the Active Directory peer. Changes to entries in Active Directory are found by using Active Directory's Dirsync search feature. Directory Server runs the Dirsync search periodically by default every five minutes to check for changes on the Active Directory server. You can change this default by setting the winSyncInterval parameter in the cn=syncAgreement_Name,cn=WindowsReplica,cn=suffix_Name,cn=mapping tree,cn=config entry. Using Dirsync ensures that only those entries that have changed since the previous search are retrieved.
In some situations, such as when synchronization is configured or there have been major changes to directory data, a total update, or resynchronization, can be run. This examines every entry in both sync peers and sends any modifications or missing entries. A full Dirsync search is initiated whenever a total update is run. See Section 16.11, “Sending Synchronization Updates” for more information.
Windows Synchronization provides some control over which entries are synchronized to grant administrators fine-grained control of the entries that are synchronized and to give sufficient flexibility to support different deployment scenarios. This control is set through different configuration attributes set in the Directory Server:
  • When creating the sync agreement, there is an option to synchronizing new Windows entries (nsDS7NewWinUserSyncEnabled and nsDS7NewWinGroupSyncEnabled) as they are created. If these attributes are set to on, then existing Windows users/groups are synchronized to the Directory Server, and users/groups as they are created are synchronized to the Directory Server.
    Within the Windows subtree, only entries with user or group object classes can be synchronized to Directory Server.
  • On the Directory Server, only entries with the ntUser or ntGroup object classes and attributes can be synchronized.
The placement of the sync agreement depends on what suffixes are synchronized; for a single suffix, the sync agreement is made for that suffix alone; for multiple suffixes, the sync agreement is made at a higher branch of the directory tree. To propagate Windows entries and updates throughout the Directory Server deployment, make the agreement between a master in a multi-master replication environment, and use that master to replicate the changes across the Directory Server deployment, as shown in Figure 16.2, “Multi-Master Directory Server — Windows Domain Synchronization”.

Important

While it is possible to configure a sync agreement on a hub server, this only allows uni-directional synchronization, from Red Hat Directory Server to Active Directory. The Active Directory server cannot sync any changes back to the hub.
It is strongly recommended that only masters in multi-master replication be used to configure synchronization agreements.

Warning

There can only be a single sync agreement between the Directory Server environment and the Active Directory environment. Multiple sync agreements to the same Active Directory domain can create entry conflicts.
Multi-Master Directory Server — Windows Domain Synchronization

Figure 16.2. Multi-Master Directory Server — Windows Domain Synchronization

Directory Server passwords are synchronized along with other entry attributes because plain-text passwords are retained in the Directory Server changelog. The Password Synchronization service is needed to catch password changes made on Active Directory. Without the Password Synchronization service, it would be impossible to have Windows passwords synchronized because passwords are hashed in Active Directory, and the Windows hashing function is incompatible with the one used by Directory Server.

16.2. Supported Active Directory Versions

16.3. Synchronizing Passwords

Password changes in a Directory Server entry can be synchronized to password attributes in Active Directory entries by using the Password Sync utility.
When passwords are synchronized, password policies are enforced on each sync peer locally. The syntax or minimum length requirements on the Directory Server apply when the password is changed in the Directory Server. When the changed password is synced over to the Windows server, the Windows password policy is enforced. The password policies themselves are not synchronized.
Configuration information is kept locally and cannot be synchronized, including the password change history and the account lockout counters.
When configuring a password policy for synchronization, consider the following points:
  • The Password Sync utility must be installed locally on the Windows machine that will be synchronized with a Directory Server.
  • Password Sync can only link the Windows machine to a single Directory Server; to sync changes with multiple Directory Server instances, configure the Directory Server for multi-master replication.
  • Password expiration warnings and times, failed bind attempts, and other password-related information is enforced locally per server and is not synchronized between sync peer servers.
  • The same bind behavior should occur on all servers. Make sure to create the same or similar password policies on both Directory Server and Active Directory servers.
  • Entries that are created for synchronization (for example, the server identities) need to have passwords that never expire. To make sure that these special users have passwords that do not expire, add the passwordExpirationTime attribute to the Directory Server entry, and give it a value of 20380119031407Z (the top of the valid range).
See Chapter 16, Synchronizing Red Hat Directory Server with Microsoft Active Directory for more information on synchronizing Directory Server and Windows users and passwords.

16.4. Steps for Configuring Windows Synchronization

Configuring synchronization is very similar to configuring replication. It requires configuring the database as a master with a changelog and creating an agreement to define synchronization. A common user identity, a sync user, connects to the Windows sync peer to send updates from the Directory Server and to check for updates to sync back to the Directory Server.

Note

To synchronize passwords (which is the only way for users to be active on both Directory Server and Active Directory), synchronization must be configured to run over TLS. Therefore, this configuration section assumes that TLS must also be configured.
Configuring synchronization over TLS is also similar to configuring replication over TLS. Both sync peers must be configured to trust each other for encrypted sessions (all password operations are performed over TLS).
All synchronization for user and group entries is passive from the Active Directory (AD) side; it is the Directory Server which sends updates on its side and polls for updates on the AD domain. For passwords, the AD server requires a separate password service; this service actively sends password changes from the AD domain to Directory Server.

16.4.1. Step 1: Configure TLS on Directory Server

The full instructions for configuring the Directory Server to run in TLS are at Section 9.4.1, “Enabling TLS in Directory Server”. Basically, the Directory Server needs to have the appropriate TLS certificates installed, be configured to run over an LDAPS port, and allow client authentication from other servers.
Two certificates must be issued and installed on both the Directory Server and the AD sync peer:
  • CA certificate, shared between the Directory Server and AD
  • Server certificates for the Directory Server and AD sync peers, which are accessible by the sync services

16.4.2. Step 2: Configure the Active Directory Domain

You can configure synchronization only with AD domain controllers. Additionally, password complexity must be enabled in AD.
To enable password complexity:
  1. Open the Group Policy Management console and create a new Group Policy Object (GPO). For details, see the Windows documentation.
  2. Right-click the GPO, and select Edit to open the Group Policy Management Editor.
  3. Navigate to Computer ConfigurationWindows SettingsSecurity SettingsAccount PoliciesPassword Policy, and double-click the policy named Password must meet complexity requirements.
  4. Enable the policy and click OK.
  5. Close the Group Policy Management Editor and the Group Policy Management console.
Configure TLS and set up a root CA on the AD server, as described in the Microsoft knowledgebase at http://technet.microsoft.com/en-us/library/cc772393%28v=ws.10%29.aspx#BKMK_AS1.
  1. Install a certificate authority.
    1. In the Administrative Tools area, open Server Manager and add a role.
    2. Select the Active Directory Certificate Services check box.
    3. Click through to the Select Role Services page, and select the Certification Authority check box.
    4. When configuring the CA, select the following options on the appropriate screens:
      • Enterprise for the setup type
      • Certification Authority Web Enrollment in the optional configuration
    5. Reboot the AD server.
  2. Set up the AD server to use the TLS server certificate.
    1. Create a certificate request .inf, using the fully-qualified domain name of the AD as the certificate subject. For example:
      ;----------------- request.inf -----------------
      
      [Version]
      
      Signature="$Windows NT$
      
      [NewRequest]
      
      Subject = "CN=ad.server.example.com, O=Engineering, L=Raleigh, S=North Carolina, C=US"
      KeySpec = 1
      KeyLength = 2048
      Exportable = TRUE
      MachineKeySet = TRUE
      SMIME = False
      PrivateKeyArchive = FALSE
      UserProtected = FALSE
      UseExistingKeySet = FALSE
      ProviderName = "Microsoft RSA SChannel Cryptographic Provider"
      ProviderType = 12
      RequestType = PKCS10
      KeyUsage = 0xa0
      
      [EnhancedKeyUsageExtension]
      
      OID=1.3.6.1.5.5.7.3.1
      
      ;-----------------------------------------------
    2. Generate the certificate request.
      # certreq -new request.inf request.req
    3. Submit the request to the AD CA. For example:
      # certreq -submit request.req certnew.cer

      Note

      If the command-line tool returns an error message, then use the Web browser to access the CA and submit the certificate request. If IIS is running, then the CA URL is http://servername/certsrv.
    4. Accept the certificate request. For example:
      # certreq -accept certnew.cer
  3. Make sure that the server certificate is present on the AD server.
    1. In the Run menu, open the MMC console.
    2. In the File menu, click Add/Remove Snap-in....
    3. Select the Certificates snap-in, and click Add to add it, and then click Next.
    4. Expand the Certificates (Local) menu on the left. Expand the Personal item and click Certificates.
    5. The new certificate should be listed with the other certificates.
  4. On the Directory Server, export the CA certificate.
    # cd /etc/dirsrv/slapd-instance_name/
    # certutil -d . -L -n "CA certificate" -a > dsca.crt
  5. Copy the exported certificate from the Directory Server to the Windows machine.
  6. Import the CA certificate from Directory Server into AD.
    1. Open Administrative Tools and select the Certificate Authority item.
    2. Expand Trusted Root Certification Authorities.
    3. Right-click the Certificates item and select Import.
    4. Browse to the downloaded Directory Server CA certificate, and click Next.
    5. Save the CA certificate in the Trusted Root Certification Authorities store.
  7. Reboot the domain controller.
To test that the server is running in TLS correctly, try searching AD over LDAPS.

16.4.3. Step 3: Select or Create the Synchronization Identity

There are two users used to configure Windows Synchronization:
  • An AD user, specified in the sync agreement.
    The user specified in the sync agreement is the entity as whom the Directory Server binds to AD to send and receive updates. The AD user should be a member of the Domain Admins group, or have equivalent rights, and must have rights to replicate directory changes.
    For information on adding users and setting privileges in AD , see the Microsoft documentation.
  • A Directory Server user, specified in the Password Sync Service.
    The user referenced in the Password Sync service must have read and write permissions to every entry within the synchronized subtree and absolutely must have write access to password attributes in Directory Server so that Password Sync can update password changes.

Note

The user cited in the sync agreement (the supplier DN) exists on the AD server. The user cited in the Password Sync configuration exists on Directory Server.
To create a sync user on Directory Server:
  1. Create a new entry, such as cn=sync user,cn=config, with a password. For example:
    # ldapmodify -a -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn: cn=sync user,cn=config
    changetype: add
    objectClass: inetorgperson
    objectClass: person
    objectClass: top
    cn: sync user
    sn: SU
    userPassword: secret
    passwordExpirationTime: 20380119031407Z
  2. Set an ACI that grants the sync user access to compare and write user passwords.
    The ACI must be set at the top of the subtree which will be synchronized. For example:
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn: ou=people,dc=example,dc=com
    changetype: modify
    add: aci
    aci: (targetattr="userPassword")(version 3.0;acl "password sync";allow (write,compare) userdn="ldap:///cn=sync user,cn=config";)
    For security reasons, the Password Sync user should not be Directory Manager and should not be part of the synchronized subtree.

16.4.4. Step 4: Install the Password Sync Service

The steps to install the Password Sync service are described in the Installing the Password Sync Service section in the Red Hat Directory Server Installation Guide.
For a list of operating systems Red Hat supports running the Password Sync service on, see Red Hat Directory Server Release Notes.

Note

The first attempt to synchronize passwords, which happens when the Password Sync application is installed, always fails because the CA certificate does not exist in Password Sync's certificate database. Adding the CA certificate is part of the configuration step of the application.

16.4.5. Step 5: Configure the Password Sync Service

Next, set up certificates that Password Sync uses to access the Directory Server over TLS:
  1. Enable TLS in Directory Server. For details, see Section 9.4.1, “Enabling TLS in Directory Server”.

    Note

    TLS is required for Password Sync to send passwords to Directory Server. The service will not send the passwords except over TLS to protect the clear text password sent from the Active Directory machine to the Directory Server machine. This means that Password Sync will not work until TLS is configured.
  2. On the Directory Server, export the server certificate.
    # certutil -d /usr/lib64/dirsrv/slapd-instance -L -n "CA certificate" -a > dsca.crt
  3. Copy the exported certificate from the Directory Server to the Windows machine.
  4. Open a command prompt on the Windows machine, and open the Password Sync installation directory.
    > cd "C:\Program Files\Red Hat Directory Password Synchronization""
  5. Create new cert8.db and key.db databases on the Windows machine.
    > certutil.exe -d . -N
  6. Import the server certificate from the Directory Server into the new certificate database.
    > certutil.exe -d . -A -n "DS CA cert" -t CT,, -a -i \path\to\dsca.crt
  7. Verify that the CA certificate was correctly imported.
    > certutil.exe -d . -L -n "DS CA cert"
  8. Reboot the Windows machine. The Password Sync service is not available until after a system reboot.

Note

If any Active Directory user accounts exist when Password Sync is first installed, then the passwords for those user accounts cannot be synchronized until they are changed because Password Sync cannot decrypt a password once it has been hashed in Active Directory.

16.4.6. Step 6: Configure the Directory Server Database for Synchronization

Just as with replication, there must be a changelog available to track and send directory changes and the Directory Server database being synchronized must be configured as a replica.

Note

If the Directory Server database is already configured for replication, this step is not necessary.
Setting up a database for replication is described in Section 15.6.1, “Configuring the Read-Write Replicas on the Supplier Servers”.

16.4.6.1. Setting up the Directory Server for Synchronization from the Console

First, enable the changelog:
  1. In the Directory Server Console, select the Configuration tab.
  2. In the left-hand navigation tree, click the Replication folder.
  3. In the main window, click the Supplier Settings tab.
  4. Check the Enable Changelog database.
    The Configuration tab

    Figure 16.3. The Configuration tab

  5. Set the changelog database directory. Click the Use default button to use the default or Browse... to select a custom directory.
  6. Save the changelog settings.
After setting up the changelog, then configure the database that will be synchronized as a replica. The replica role should be either a single-master or multi-master.

Important

While it is possible to configure a sync agreement on a hub server, this only allows uni-directional synchronization, from Red Hat Directory Server to AD. The AD server cannot sync any changes back to the hub.
It is strongly recommended that only masters in multi-master replication be used to configure synchronization agreements.
  1. In the Directory Server Console, select the Configuration tab.
  2. In the left-hand navigation tree, click the Replication folder, then click the name of the database to synchronize.
    By default, there are two databases, NetscapeRoot for directory configuration and userRoot for directory entries. Other databases may be listed if they have been added to Directory Server.
  3. Check the Enable Replica check box, and select the radio button by the type of replica which the database is.
    The Enable Replica check box

    Figure 16.4. The Enable Replica check box

  4. In the Update Settings section, either select or add a supplier DN. This is the user account as which synchronization process will be run. As mentioned in Section 16.4.3, “Step 3: Select or Create the Synchronization Identity”, this user must be on the Directory Server and must have the access right for the userPassword attribute of all users that are to be synchronized.
    The Update Settings section

    Figure 16.5. The Update Settings section

  5. Save the replication settings for the database.

Note

For more information on replication settings, see Chapter 15, Managing Replication.

16.4.6.2. Setting up the Directory Server for Synchronization from the Command Line

First, enable the changelog:
# ldapmodify -a -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: cn=changelog5,cn=config
changetype: add
objectclass: top
objectclass: extensibleObject
cn: changelog5
nsslapd-changelogdir: /var/lib/dirsrv/slapd-instance_name/changelogdb
nsslapd-changelogmaxage: 7d
Then, create the supplier replica entry:
# ldapmodify -a -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: cn=sync replica,cn="dc=example,dc=com",cn=mapping tree,cn=config
changetype: add
objectclass: top
objectclass: nsds5replica
objectclass: extensibleObject
cn: sync replica
nsds5replicaroot: dc=example,dc=com
nsds5replicaid: 7
nsds5replicatype: 3
nsds5flags: 1
nsds5ReplicaPurgeDelay: 604800
nsds5ReplicaBindDN: cn=sync user,cn=config
These different parameters are described in more detail in the Configuration, Command, and File Reference and Section 15.2.1, “Configuring Suppliers from the Command Line”.

16.4.7. Step 7: Create the Synchronization Agreement

Create the synchronization agreement.

Note

If secure binds are required for simple password authentication (Section 19.11.1, “Requiring Secure Binds”), then any replication operations will fail unless they occur over a secure connection. Using a secure connection (LDAPS or StartTLS) is recommended, anyway.

16.4.7.1. Creating the Synchronization Agreement from the Console

  1. In the Directory Server Console, select the Configuration tab.
  2. In the left-hand navigation tree, click Replication, then right-click on the database to sync. The default user database is userRoot, but additional databases are added as new suffixes are added to the Directory Server.
    Alternatively, highlight the database, and in the top tool bar, click Object.
  3. Select New Windows Synchronization Agreement from the menu.
  4. In the two fields, supply a name and description of the synchronization agreement. Hit Next.
  5. In the Windows Sync Server Info window, fill in the AD information in the Windows Domain Information area.
    • The name of the Windows domain.
    • What kinds of entries to synchronize; users and groups are synchronized independently. When a type of entry is chosen, then all of the entries of that type that are found in the Windows subtree are created in the Directory Server.
    • The Windows and Directory Server subtree information; this is automatically filled in.
    • The host name, IPv4 address, or IPv6 address of the domain controller
    • The Windows server's port number
  6. Set the connection type. There are three options:
    • Use LDAP. This sets either a standard, unencrypted connection.
    • Use TLS/SSL. This uses a secure connection over the server's secure LDAPS port, such as 636. Both the Directory Server and the Windows server must be properly configured to run in TLS for this connection and must have installed each other's CA certificates in order to trust their server certificates.
    • Use Start TLS. This uses Start TLS to establish a secure connection over the server's standard port. Like regular TLS, these peer servers must be able to trust each other's certificates.
    Using either TLS or Start TLS is recommended for security reasons. TLS or Start TLS is required for synchronizing passwords because AD refuses to modify passwords unless the connection is TLS-protected.
  7. Fill in the authentication information in the Bind as... and Password fields with the sync ID information. This user must exist in the AD.
  8. Save the sync agreement.

Note

By default, Windows Synchronization polls the AD peer every five (5) minutes to check for changes. In the sync agreement summary, this is displayed as the Update Interval. The update interval can be changed by editing the winSyncInterval attribute manually. See Section 16.12.2, “Adding and Editing the Synchronization Agreement in the Command Line”.
When the agreement is complete, the new sync agreement is listed under the suffix.

16.4.7.2. Creating the Synchronization Agreement from the Command Line

It is also possible to add the sync agreement through the command line.
# ldapmodify -a -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: cn=replication_agreement_name,cn=replica,cn="dc=example,dc=com",cn=mapping tree,cn=config
changetype: add
objectclass: top
objectclass: nsDSWindowsReplicationAgreement
cn: replication_agreement_name
nsds7WindowsReplicaSubtree: cn=Users,dc=ad1
nsds7DirectoryReplicaSubtree: ou=People,dc=example,dc=com
nsds7NewWinUserSyncEnabled: on
nsds7NewWinGroupSyncEnabled: on
nsds7WindowsDomain: ad1
nsDS5ReplicaRoot: dc=example,dc=com
nsDS5ReplicaHost: ad1.windows-server.com
nsDS5ReplicaPort: 389
nsDS5ReplicaBindDN: cn=sync user,cn=config
nsDS5ReplicaCredentials: {DES}ffGad646dT0nnsT8nJOaMA==
nsDS5ReplicaTransportInfo: TLS
winSyncInterval: 1200
For descriptions of the parameters used in the example and other attributes you can set, see the Red Hat Directory Server Configuration, Command, and File Reference.

16.4.8. Step 8: Configure Directory Server User and Group Entries for Synchronization

Add the ntUser and ntGroup object classes to any user and group entries, respectively, which will be synchronized, along with any required attributes. Only Directory Server entries with those object classes are synchronized. AD entries which are synced over to Directory Server have those object classes automatically.
Whenever the appropriate object classes are added to an entry, both for new entries and existing entries, the entry is synced over at the next incremental update.
Configuring Directory Server user entries for synchronization is described in Section 16.5.3, “Configuring User Synchronization for Directory Server Users”, and configuring Directory Server group entries for synchronization is described in Section 16.6.4, “Configuring Group Synchronization for Directory Server Groups”.

16.4.9. Step 9: Begin Synchronization

After the synchronization agreement has been created, start the synchronization.

Starting the Synchronization Using the Command Line

To start synchronization using the command line:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: cn=replication_agreement_name,cn=replica,cn="dc=example,dc=com",cn=mapping tree,cn=config
changetype: modify
replace: nsds5beginreplicarefresh
nsds5beginreplicarefresh: start
When the initialization is complete, Directory Server automatically removes the nsds5BeginReplicaRefresh attribute from the replication agreement entry.

Starting the Synchronization Using the Console

  1. Go to the Configuration tab in the Console.
  2. Open the Replication folder and expand the appropriate database.
  3. Select the sync agreement.
  4. Right-click on the agreement or open the Object menu.
  5. Select Initiate Full Re-synchronization.
If synchronization stops for any reason, begin another total update (resynchronization) by selecting this from the sync agreement menu. Beginning a total update (resynchronization) will not delete or overwrite the databases.

16.5. Synchronizing Users

Users are not automatically synced between Directory Server and Active Directory. Synchronization both directions has to be configured:
  • Users in the Active Directory domain are synced if it is configured in the sync agreement by selecting the Sync New Windows Users option. All of the Windows users are copied to the Directory Server when synchronization is initiated and then new users are synced over when they are created.
  • A Directory Server user account is synchronized to Active Directory through specific attributes that are present on the Directory Server entry. Any Directory Server entry must have the ntUser object class and the ntUserCreateNewAccount attribute; the ntUserCreateNewAccount attribute (even on an existing entry) signals the Directory Server Windows Synchronization plug-in to write the entry over to the Active Directory server.
    New or modified user entries with the ntUser object class added are created and synced over to the Windows machine at the next regular update, which is a standard poll of entry.

Note

A user is not active on the Active Directory domain until it has a password. When an existing user is modified to have the required Windows attributes, that user entry will be synced over to the Active Directory domain, but will not be able to log in until the password is changed on the Directory Server side or an administrator sets the password on Active Directory. This is because passwords stored in the Directory Server are encrypted, and Password Sync cannot sync already encrypted passwords.
To make the user active on the Active Directory domain, reset the user's password.
All synchronized entries in the Directory Server, whether they originated in the Directory Server or in Active Directory, have special synchronization attributes:
  • ntUserDomainId. This corresponds to the sAMAccountName attribute for Active Directory entries.
  • ntUniqueId. This contains the value of the objectGUID attribute for the corresponding Windows entry. This attribute is set by the synchronization process and should not be set or modified manually.
  • ntUserDeleteAccount. This attribute is set automatically when a Windows entry is synced over but must be set manually for Directory Server entries. If ntUserDeleteAccount has the value true, the corresponding Windows entry be deleted when the Directory Server entry is deleted. Otherwise, the entry remains in Active Directory, but is removed from the Directory Server database if it is deleted in the Directory Server.
Setting ntUserCreateNewAccount and ntUserDeleteAccount on Directory Server entries allows the Directory Manager precise control over which users within the synchronized subtree are synced on Active Directory.

16.5.1. User Attributes Synchronized between Directory Server and Active Directory

Only a subset of Directory Server and Active Directory attributes are synchronized. These attributes are hard-coded and are defined regardless of which way the entry is being synchronized. Any other attributes present in the entry, either in Directory Server or in Active Directory, remain unaffected by synchronization.
Some attributes used in Directory Server and Active Directory are identical. These are usually attributes defined in an LDAP standard, which are common among all LDAP services. These attributes are synchronized to one another exactly. Table 16.2, “User Schema That Are the Same in Directory Server and Windows Servers” shows attributes that are the same between the Directory Server and Windows servers.
Some attributes define the same information, but the names of the attributes or their schema definitions are different. These attributes are mapped between Active Directory and Directory Server, so that attribute A in one server is treated as attribute B in the other. For synchronization, many of these attributes relate to Windows-specific information. Table 16.1, “User Schema Mapped between Directory Server and Active Directory” shows the attributes that are mapped between the Directory Server and Windows servers.
For more information on the differences in ways that Directory Server and Active Directory handle some schema elements, see Section 16.5.2, “User Schema Differences between Red Hat Directory Server and Active Directory”.

Table 16.1. User Schema Mapped between Directory Server and Active Directory

Directory Server Active Directory
cn[a] name
ntUserDomainId sAMAccountName
ntUserHomeDir homeDirectory
ntUserScriptPath scriptPath
ntUserLastLogon lastLogon
ntUserLastLogoff lastLogoff
ntUserAcctExpires accountExpires
ntUserCodePage codePage
ntUserLogonHours logonHours
ntUserMaxStorage maxStorage
ntUserProfile profilePath
ntUserParms userParameters
ntUserWorkstations userWorkstations
[a] The cn is treated differently than other synced attributes. It is mapped directly (cn to cn) when syncing from Directory Server to Active Directory. When syncing from Active Directory to Directory Server, however, cn is mapped from the name attribute on Windows to the cn attribute in Directory Server.

Table 16.2. User Schema That Are the Same in Directory Server and Windows Servers

cn[a] physicalDeliveryOfficeName
description postOfficeBox
destinationIndicator postalAddress
facsimileTelephoneNumber postalCode
givenname registeredAddress
homePhone sn
homePostalAddress st
initials street
l telephoneNumber
mail teletexTerminalIdentifier
mobile telexNumber
o title
ou usercertificate
pager x121Address
[a] The cn is treated differently than other synced attributes. It is mapped directly (cn to cn) when syncing from Directory Server to Active Directory. When syncing from Active Directory to Directory Server, however, cn is mapped from the name attribute on Windows to the cn attribute in Directory Server.

16.5.2. User Schema Differences between Red Hat Directory Server and Active Directory

Although Active Directory supports the same basic X.500 object classes as Directory Server, there are a few incompatibilities of which administrators should be aware.

16.5.2.1. Values for cn Attributes

In Directory Server, the cn attribute can be multi-valued, while in Active Directory this attribute must have only a single value. When the Directory Server cn attribute is synchronized, then, only one value is sent to the Active Directory peer.
What this means for synchronization is that,potentially, if a cn value is added to an Active Directory entry and that value is not one of the values for cn in Directory Server, then all of the Directory Server cn values are overwritten with the single Active Directory value.
One other important difference is that Active Directory uses the cn attribute attribute as its naming attribute, where Directory Server uses uid. This means that there is the potential to rename the entry entirely (and accidentally) if the cn attribute is edited in the Directory Server. If that cn change is written over to the Active Directory entry, then the entry is renamed, and the new named entry is written back over to Directory Server.

16.5.2.2. Password Policies

Both Active Directory and Directory Server can enforce password policies such as password minimum length or maximum age. Windows Synchronization makes no attempt to ensure that the policies are consistent, enforced, or synchronized. If password policy is not consistent in both Directory Server and Active Directory, then password changes made on one system may fail when synced to the other system. The default password syntax setting on Directory Server mimics the default password complexity rules that Active Directory enforces.

16.5.2.3. Values for street and streetAddress

Active Directory uses the attribute streetAddress for a user or group's postal address; this is the way that Directory Server uses the street attribute. There are two important differences in the way that Active Directory and Directory Server use the streetAddress and street attributes, respectively:
  • In Directory Server, streetAddress is an alias for street. Active Directory also has the street attribute, but it is a separate attribute that can hold an independent value, not an alias for streetAddress.
  • Active Directory defines both streetAddress and street as single-valued attributes, while Directory Server defines street as a multi-valued attribute, as specified in RFC 4519.
Because of the different ways that Directory Server and Active Directory handle streetAddress and street attributes, there are two rules to follow when setting address attributes in Active Directory and Directory Server:
  • Windows Synchronization maps streetAddress in the Windows entry to street in Directory Server. To avoid conflicts, the street attribute should not be used in Active Directory.
  • Only one Directory Server street attribute value is synced to Active Directory. If the streetAddress attribute is changed in Active Directory and the new value does not already exist in Directory Server, then all street attribute values in Directory Server are replaced with the new, single Active Directory value.

16.5.2.4. Constraints on the initials Attribute

For the initials attribute, Active Directory imposes a maximum length constraint of six characters, but Directory Server does not have a length limit. If an initials attribute longer than six characters is added to Directory Server, the value is trimmed when it is synchronized with the Active Directory entry.

16.5.3. Configuring User Synchronization for Directory Server Users

For Directory Server users to be synchronized over to Active Directory, the user entries must have the appropriate sync attributes set.

16.5.3.1. Configuring User Synchronization in the Console

  1. In the Directory Server Console, select the Directory tab.
  2. For an existing entry, right-click the entry, and click Properties to open the property editor for the entry.
    For a new entry, right-click the main entry in the left window to add the new entry, select User, and then fill in the required entry attributes.
  3. On the left side of the Property Editor, click the NT User link.
  4. In the NT User tab, check the Enable NT Attributes check box.
  5. To enable synchronization, two fields are required:
    • Setting a NT User ID
    • Selecting the Create New NT Account check box
  6. Selecting the Delete NT Account check box means that the corresponding Windows user is deleted if the Directory Server entry is deleted.
  7. Set the other Windows attributes. These attributes are mapped to relevant Windows attributes.
    Additional ntUser attributes can be created either by using the Advanced button; see Section 3.1.4, “Updating a Directory Entry”.

Note

Reset the user's password.
A user is not active on the Active Directory domain until it has a password. When an existing user is modified to have the required Windows attributes, that user entry will be synced over to the Active Directory domain, but will not be able to log in until the password is changed on the Directory Server side or an administrator sets the password on Active Directory. Password Sync cannot sync encrypted passwords.
So, to make the user active on the Active Directory domain, reset the user's password.

16.5.3.2. Configuring User Synchronization in the Command Line

To enable synchronization through the command line, add the required sync attributes to an entry or create an entry with those attributes.
Three schema elements are required for synchronization:
  • The ntUser object class
  • The ntUserDomainId attribute, to give the Windows ID
  • The ntUserCreateNewAccount attribute, to signal to the synchronization plug-in to sync the Directory Server entry over to Active Directory
For example, using the ldapmodify utility:
dn: uid=scarter,ou=People,dc=example,dc=com
changetype: modify
add: objectClass
objectClass:ntUser
-
add: ntUserDomainId
ntUserDomainId: Sam Carter
-
add: ntUserCreateNewAccount
ntUserCreateNewAccount: true
-
add: ntUserDeleteAccount
ntUserDeleteAccount: true
Many additional Windows and user attributes can be added to the entry. All of the schema which is synchronized is listed in Section 16.5.1, “User Attributes Synchronized between Directory Server and Active Directory”. Windows-specific attributes, belonging to the ntUser object class, are described in more detail in the Red Hat Directory Server 10 Configuration, Command, and File Reference.

Note

Reset the user's password.
A user is not active on the Active Directory domain until it has a password. When an existing user is modified to have the required Windows attributes, that user entry will be synced over to the Active Directory domain, but will not be able to log in until the password is changed on the Directory Server side or an administrator sets the password on Active Directory. Password Sync cannot sync encrypted passwords.
So, to make the user active on the Active Directory domain, reset the user's password.

16.5.4. Configuring User Synchronization for Active Directory Users

Synchronization for Windows users (users which originate in the Active Directory domain) is configured in the sync agreement.

16.5.4.1. Configuring User Synchronization in the Console

  1. Open the Configuration tab and expand the Replication folder.
  2. Open the appropriate database, and select the sync agreement.
  3. Open the Connection tab.
  4. Check the New Windows User Sync check box to enable users sync. To disable sync, uncheck the box.
For new sync agreements, select the corresponding users sync check box in the sync agreement creation wizard.

16.5.4.2. Configuring User Synchronization in the Command Line

The attribute to set Active Directory user sync is nsds7NewWinUserSyncEnabled and is set on the sync agreement. To enable user sync, add this attribute to the sync agreement or create a sync agreement with this attribute set to on using ldapmodify:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: cn=replication_agreement_name,cn=replica,cn="dc=example,dc=com",cn=mapping tree,cn=config
changetype: modify
replace: nsds7NewWinUserSyncEnabled
nsds7NewWinUserSyncEnabled: on
To disable user sync, set nsds7NewWinUserSyncEnabled: off.

16.6. Synchronizing Groups

Like user entries, groups are not automatically synced between Directory Server and Active Directory. Synchronization both directions has to be configured:
  • Groups in the Active Directory domain are synced if it is configured in the sync agreement by selecting the Sync New Windows Groups option. All of the Windows groups are copied to the Directory Server when synchronization is initiated and then new groups are synced over as they are created.
  • A Directory Server group account is synchronized to Active Directory through specific attributes that are present on the Directory Server entry. Any Directory Server entry must have the ntGroup object class and the ntGroupCreateNewGroup attribute; the ntGroupCreateNewGroup attribute (even on an existing entry) signals Directory Server Windows Synchronization to write the entry over to the Active Directory server.
    New or modified groups that have the ntGroup object class are created and synced over to the Windows machine at the next regular update.

Important

When a group is synced, the list of all of its members is also synced. However, the member entries themselves are not synced unless user sync is enabled and applies to those entries.
This could create a problem when an application or service tries to do a modify operation on all members in a group on the Active Directory server, if some of those users do not exist.
Additionally, groups have a few other common attributes:
  • Two attributes control whether Directory Server groups are created and deleted on Active Directory, ntGroupCreateNewGroup and ntGroupDeleteGroup.
    ntGroupCreateNewGroup is required to sync Directory Server groups over to Active Directory.
  • ntUserDomainId contains the unique ID for the entry on the Active Directory domain. This is the only required attribute for the ntGroup object class.
  • ntGroupType is the type of Windows group. Windows group types are global/security, domain local/security, builtin, universal/security, global/distribution, domain local/distribution, or universal/distribution. This is set automatically for Windows groups that are synchronized over, but this attribute must be set manually on Directory Server entries before they can be synced.

16.6.1. About Windows Group Types

In Active Directory, there are two major types of groups: security and distribution. Security groups are most similar to groups in Directory Server, since security groups can have policies configured for access controls, resource restrictions, and other permissions. Distribution groups are for mailing distribution. These are further broken down into global and local groups. The Directory Server ntGroupType supports all four group types:
  • -2147483646 for global/security (the default)
  • -2147483644 for domain local/security
  • -2147483643 for builtin
  • -2147483640 for universal/security
  • 2 for global/distribution
  • 4 for domain local/distribution
  • 8 for universal/distribution

16.6.2. Group Attributes Synchronized between Directory Server and Active Directory

Only a subset of Directory Server and Active Directory attributes are synchronized. These attributes are hard-coded and are defined regardless of which way the entry is being synchronized. Any other attributes present in the entry, either in Directory Server or in Active Directory, remain unaffected by synchronization.
Some attributes used in Directory Server and Active Directory group entries are identical. These are usually attributes defined in an LDAP standard, which are common among all LDAP services. These attributes are synchronized to one another exactly. Table 16.4, “Group Entry Attributes That Are the Same between Directory Server and Active Directory” shows attributes that are the same between the Directory Server and Windows servers.
Some attributes define the same information, but the names of the attributes or their schema definitions are different. These attributes are mapped between Active Directory and Directory Server, so that attribute A in one server is treated as attribute B in the other. For synchronization, many of these attributes relate to Windows-specific information. Table 16.3, “Group Entry Attribute Mapping between Directory Server and Active Directory” shows the attributes that are mapped between the Directory Server and Windows servers.
For more information on the differences in ways that Directory Server and Active Directory handle some schema elements, see Section 16.6.3, “Group Schema Differences between Red Hat Directory Server and Active Directory”.

Table 16.3. Group Entry Attribute Mapping between Directory Server and Active Directory

Directory Server Active Directory
cn name
ntUserDomainID name
ntGroupType groupType
uniqueMember
member
Member[a]
[a] The Member attribute in Active Directory is synced to the uniqueMember attribute in Directory Server.

Table 16.4. Group Entry Attributes That Are the Same between Directory Server and Active Directory

cn o
description ou
l seeAlso
mail

16.6.3. Group Schema Differences between Red Hat Directory Server and Active Directory

Although Active Directory supports the same basic X.500 object classes as Directory Server, there are a few incompatibilities of which administrators should be aware.
Nested groups (where a group contains another group as a member) are supported and for Windows Synchronization are synchronized. However, Active Directory imposes certain constraints as to the composition of nested groups. For example, a global group is not allowed to contain a domain local group as a member. Directory Server has no concept of local and global groups, and, therefore, it is possible to create entries on the Directory Server side that violate Active Directory's constraints when synchronized.

16.6.4. Configuring Group Synchronization for Directory Server Groups

For Directory Server groups to be synchronized over to Active Directory, the group entries must have the appropriate sync attributes set.

16.6.4.1. Configuring Group Synchronization in the Console

  1. In the Directory Server Console, select the Directory tab.
  2. Right-click the group entry, and click Advanced to open the advanced property editor for the entry. All of the sync-related attributes must be added manually, so only the advanced property editor can set the attributes.
  3. Click the objectClasses field, and then click the Add Value button.
  4. Select the ntGroup object class.
  5. Setting the ntGroup object class automatically adds the ntUserDomainId attribute. This attribute is required, so add a value.
  6. To enable synchronization, click the Add Attribute button, and select the ntGroupCreateNewGroup attribute from the list. Then, set its value to true. This signals to the sync plug-in that the entry should be added to the Active Directory directory.
    To delete the group entry from the Active Directory domain if it is deleted from the Directory Server database, set the ntGroupDeleteGroup attribute and set it to true.
  7. Add any other Windows attributes for the Directory Server entry. The available attributes are listed in Section 16.6.2, “Group Attributes Synchronized between Directory Server and Active Directory”.
    If the ntGroupType is not added, then the group is automatically added as a global security group (ntGroupType:-2147483646).

16.6.4.2. Configuring Group Synchronization in the Command Line

To enable synchronization through the command line, add the required sync attributes to an entry or create an entry with those attributes.
Three schema elements are required for synchronization:
  • The ntGroup object class.
  • The ntUserDomainId attribute, to give the Windows ID for the entry.
  • The ntGroupCreateNewGroup attribute, to signal to the synchronization plug-in to sync the Directory Server entry over to Active Directory.
    The ntGroupDeleteGroup attribute is optional, but this sets whether to delete the entry automatically from the Active Directory domain if it is deleted in the Directory Server.
It is also recommended to add the ntGroupType attribute. If this attribute is not specified, then the group is automatically added as a global security group (ntGroupType:-2147483646).
For example, using ldapmodify:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: cn=Example Group,ou=Groups,dc=example,dc=com
changetype: modify
add: objectClass
objectClass:ntGroup
-
add: ntUserDomainId
ntUserDomainId: example-group
-
add: ntGroupCreateNewGroup
ntGroupCreateNewGroup: true
-
add: ntGroupDeleteGroup
ntGroupDeleteGroup: true
-
add: ntGroupType
ntGroupType: 2
Many additional Windows and group attributes can be added to the entry. All of the schema which is synchronized is listed in Section 16.6.2, “Group Attributes Synchronized between Directory Server and Active Directory”. Windows-specific attributes, belonging to the ntGroup object class, are described in more detail in the Red Hat Directory Server 10 Configuration, Command, and File Reference.

16.6.5. Configuring Group Synchronization for Active Directory Groups

Synchronization for Windows users (users which originate in the Active Directory domain) is configured in the sync agreement.

16.6.5.1. Configuring Group Synchronization in the Console

  1. Open the Configuration tab and expand the Replication folder.
  2. Open the appropriate database, and select the sync agreement.
  3. Open the Connection tab.
  4. Check the New Windows Group Sync check box to enable group sync. To disable sync, uncheck the box.
For new sync agreements, select the corresponding group sync check box in the sync agreement creation wizard.

16.6.5.2. Configuring Group Synchronization in the Command Line

The attribute to set Active Directory group sync is nsds7NewWinGroupSyncEnabled and is set on the sync agreement. To enable group sync, add this attribute to the sync agreement or create a sync agreement with this attribute set to on. Using ldapmodify:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: cn=replication_agreement_name,cn=replica,cn="dc=example,dc=com",cn=mapping tree,cn=config
changetype: modify
replace: nsds7NewWinGroupSyncEnabled
nsds7NewWinGroupSyncEnabled: on
To disable group sync, set nsds7NewWinGroupSyncEnabled: off.

16.7. Configuring Uni-Directional Synchronization

As Figure 16.1, “Active Directory — Directory Server Synchronization Process” illustrates, synchronization is bi-directional by default. That means that changes in Active Directory are sent to Directory Server and changes on Directory Server are sent to Active Directory.
It is possible to create uni-directional synchronization, where changes are only sent one-way. This is similar to a master-consumer relationship[2] as opposed to multi-master.
An additional attribute for the sync agreement, oneWaySync, enables uni-directional synchronization and specifies the direction to send changes. The possible values are fromWindows (for Active Directory to Directory Server sync) and toWindows (for Directory Server to Active Directory sync). If this attribute is absent, then synchronization is bi-directional.
Uni-Directional Synchronization

Figure 16.6. Uni-Directional Synchronization

The synchronization process itself is the mostly same for bi-directional and uni-directional synchronization. It uses the same sync interval and configuration. The only difference is in how sync information is requested.
For Windows Active Directory to Directory Server synchronization, during the regular synchronization update interval, the Directory Server contacts the Active Directory server and sends the DirSync control to request updates. However, the Directory Server does not send any changes or entries from its side. So, the sync update consists of the Active Directory changes being sent to and updating the Directory Server entries.
For Directory Server to Active Directory synchronization, the Directory Server sends entry modifications to the Active Directory server in a normal update, but it does not include the DirSync control so that it does not request any updates from the Active Directory side.
To enable uni-directional sync:
  1. Create the synchronization agreement, as in Section 16.4.7, “Step 7: Create the Synchronization Agreement”.
  2. There is no option in the Directory Server Console to set uni-directional sync when the agreement is initially created. Edit the sync agreement to contain the oneWaySync attribute. Using ldapmodify:
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn: cn=replication_agreement_name,cn=replica,cn="dc=example,dc=com",cn=mapping tree,cn=config
    changetype: modify
    add: oneWaySync
    oneWaySync: fromWindows

Note

Enabling uni-directional sync does not automatically prevent changes on the un-synchronized server, and this can lead to inconsistencies between the sync peers between sync updates. For example, uni-directional sync is configured to go from Active Directory to Directory Server, so Active Directory is (in essence) the data master. If an entry is modified or even deleted on the Directory Server, then the Directory Server information is different than the information and those changes are never carried over to Active Directory. During the next sync update, the edits are overwritten on the Directory Server and the deleted entry is re-added.
To prevent data inconsistency, use access control rules to prevent editing or deleting entries within the synchronized subtree on the unsynced server. Access controls for Directory Server are covered in Chapter 18, Managing Access Control. For Active Directory, see the appropriate Windows documentation.
Uni-directional sync does not affect password synchronization. Even when oneWaySync is set to toWindows, after updating a password on the Active Directory server, the password is sent to the Directory Server.

16.8. Configuring Multiple Subtrees and Filters in Windows Synchronization

Windows Synchronization is designed to synchronize between multiple pairs of subtrees on the Directory Server (DS) and Active Directory (AD). By using filters, only specified entries under a subtree are synchronized.

Multiple Subtrees in Windows Synchronization

To synchronize among multiple subtree pairs, configure the Directory Server and the Active Directory subtrees in the winSyncSubtreePair parameter in the Windows sync agreement. Use ldapmodify to set multiple subtrees as follows:
changetype: modify
add: winSyncSubtreePair
winSyncSubtreePair: ou=OU1,dc=DSexample,dc=com:ou=OU1,DC=ADexample,DC=com
If winSyncSubtreePair is not set, the nsds7WindowsReplicaSubtree AD subtree parameter and the nsds7DirectoryReplicaSubtree DS subtree parameter are used for the synchronization target checks instead. Otherwise, these two parameters are ignored.

Filters in Windows Synchronization

You can set a filter that selects data to be synchronized in the following parameters:
  • winSyncWindowsFilter sets an additional filter on the Active Directory server,
  • winSyncDirectoryFilter parameter sets an additional filter on the Directory Server.
In the following example, ldapmodify is used to synchronize entries whose CN contains user or group:
changetype: modify
add: winSyncWindowsFilter
winSyncWindowsFilter: (|(cn=*user*)(cn=*group*))
-
add: winSyncDirectoryFilter
winSyncDirectoryFilter: (|(uid=*user*)(cn=*group*))

16.9. Synchronizing POSIX Attributes for Users and Groups

A subset of all possible user and attributes are synchronized between Active Directory and Red Hat Directory Server. Some attributes are mapped, where there are differences between Active Directory and Directory Server schemas, and some attributes are matched directly. The attributes (matched and mapped) which are synchronized are listed in Section 16.5.1, “User Attributes Synchronized between Directory Server and Active Directory” and Section 16.6.2, “Group Attributes Synchronized between Directory Server and Active Directory”.
By default, only those attributes are synchronized.
One type of attribute that is missing from that sync list is any POSIX-related attribute. On Linux systems, system users and groups are identified as POSIX entries, and LDAP POSIX attributes contain that required information. However, when Windows users are synced over, they have ntUser and ntGroup attributes automatically added which identify them as Windows accounts, but no POSIX attributes are synced over (even if they exist on the Active Directory entry) and no POSIX attributes are added on the Directory Server side.
The Posix Winsync API Plug-in synchronizes POSIX attributes between Active Directory and Directory Server entries.

Note

All POSIX attributes (such as uidNumber, gidNumber, and homeDirectory) are synchronized between Active Directory and Directory Server entries. However, if a new POSIX entry or POSIX attributes are added to an existing entry in the Directory Server, only the POSIX attributes are synchronized over to the Active Directory corresponding entry. The POSIX object class (posixAccount for users and posixGroup for groups) is not added to the Active Directory entry.

16.9.1. Enabling POSIX Attribute Synchronization

The Posix Winsync API Plug-in is disabled by default and must be enabled for POSIX attributes to be synchronized from Active Directory user and group entries to the corresponding Directory Server entries.
  1. Set the nsslapd-pluginEnabled attribute to on.
    ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn: cn=Posix Winsync API,cn=plugins,cn=config
    changetype: modify
    replace: nsslapd-pluginEnabled
    nsslapd-pluginEnabled: on

    Note

    The precedence must be below 50 so that the Posix sync plug-in is loaded first. In the default configuration, the precedence is 25, and this value can remain the same in most deployments.
  2. Restart the Directory Server to load the new configuration.

16.9.2. Changing Posix Group Attribute Synchronization Settings

There are multiple plug-in attributes that can be set to control how the POSIX group attributes and group members are synced from the Active Directory entry to the corresponding Directory Server group and user entries. For details, see the corresponding section in the Red Hat Directory Server Configuration, Command, and File Reference.
The defaults can be used for most deployments, but the settings can be changed depending on the Active Directory environment. For example, to enable nested group mappings:
  1. Use ldapmodify to change the attribute to the appropriate setting:
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn: cn=Posix Winsync API,cn=plugins,cn=config
    changetype: modify
    replace: posixWinsyncMapNestedGrouping
    posixWinsyncMapNestedGrouping: true
  2. Restart the Directory Server to load the new configuration.

16.10. Deleting and Resurrecting Entries

This section describes how enabling synchronization affects deleted entries on the sync peers and how resurrected entries are handled.

16.10.1. Deleting Entries

All changes on an Active Directory peers are always synced back to the Directory Server. This means that when an Active Directory group or user account is deleted on the Active Directory domain, the deletion is automatically synced back to the Directory Server sync peer server.
On Directory Server, on the other hand, when a Directory Server account is deleted, the corresponding entry on Active Directory is only deleted if the Directory Server entry has the ntUserDeleteAccount or ntGroupDeleteGroup attribute set to true.

Note

When a Directory Server entry is synchronized over to Active Directory for the first time, Active Directory automatically assigns it a unique ID. At the next synchronization interval, the unique ID is synchronized back to the Directory Server entry and stored as the ntUniqueId attribute. If the Directory Server entry is deleted on Active Directory before the unique ID is synchronized back to Directory Server, the entry will not be deleted on Directory Server. Directory Server uses the ntUniqueId attribute to identify and synchronize changes made on Active Directory to the corresponding Directory Server entry; without that attribute, Directory Server will not recognize the deletion.
To delete the entry on Active Directory and then synchronize the deletion over to Directory Server, wait the length of the winSyncInterval (by default, five minutes) after the entry is created before deleting it so that the ntUniqueId attribute is synchronized.

16.10.2. Resurrecting Entries

It is possible to add deleted entries back in Directory Server; the deleted entries are called tombstone entries. When a deleted entry which was synced between Directory Server and Active Directory is re-added to Directory Server, the resurrected Directory Server entry has all of its original attributes and values. This is called tombstone reanimation. The resurrected entry includes the original ntUniqueId attribute which was used to synchronize the entries, which signals to the Active Directory server that this new entry is a tombstone entry.
Active Directory resurrects the old entry and preserves the original unique ID for the entry.
For Active Directory entries, when the tombstone entry is resurrected on Directory Server, all of the attributes of the original Directory Server are retained and are still included in the resurrected Active Directory entry.

16.11. Sending Synchronization Updates

Synchronization occurs as frequently as is set in the winSyncInterval setting (for retrieving changes from the Active Directory domain) or nsds5replicaupdateschedule setting (for pushing changes from the Directory Server). By default, changes are retrieved from Active Directory every five minutes, and changes from the Directory Server are sent immediately.
A sync update can be triggered manually. It is also possible to do a full resynchronization, which sends and pulls every entry in the Directory Server and Active Directory as if it were new. A full resynchronization includes existing Directory Server entries which may not have previously been synchronized.

16.11.1. Performing a Manual Incremental Synchronization

During normal operations, all the updates made to entries in the Directory Server that need to be sent to Active Directory are collected the changelog and then replayed during an incremental update.
  1. Go to the Configuration tab in the Console.
  2. Open the Replication folder and expand the appropriate database.
  3. Select the sync agreement.
  4. Right-click on the agreement or open the Object menu.
  5. Select Send and Receive Updates from the drop down menu.

16.11.2. Performing a Full Synchronization

If there have been major changes to data, or synchronization attributes are added to pre-existing Directory Server entries, it is necessary to initiate a resynchronization. Resynchronization is a total update; the entire contents of synchronized subtrees are examined and, if necessary, updated. Resynchronization is done without using the changelog. This is similar to initializing or reinitializing a consumer in replication.

16.11.2.1. Performing a Full Synchronization using the Console

To perform a full synchronization:
  1. Go to the Configuration tab in the Console.
  2. Open the Replication folder and expand the appropriate database.
  3. Select the sync agreement.
  4. Right-click on the agreement or open the Object menu.
  5. Select Initialize Full Re-synchronization from the drop down menu.
    Resynchronizing will not delete data on the sync peer; it sends and receives all updates and add any new or modified Directory Server entries; for example, it adds a pre-existing Directory Server user that had the ntUser object class added.

16.11.2.2. Performing a Full Synchronization using the Command Line

To start a full synchronization using the command line, add the nsDS5BeginReplicaRefresh attribute with the start value to the synchronization agreement.
For example, to start a full synchronization for the Example agreement:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: cn=replication_agreement_name,cn=replica,cn="dc=example,dc=com",cn=mapping tree,cn=config
changetype: modify
add: nsDS5BeginReplicaRefresh
nsDS5BeginReplicaRefresh: start
After the synchronization, Directory Server automatically removes the nsDS5BeginReplicaRefresh attribute from the agreement entry.

16.11.3. Checking Synchronization Status

Check synchronization status in the Replication tab in the Status of the Console. Highlight the synchronization agreement to monitor, and the relevant information should appear in the right-hand pane. The Status area shows whether the last incremental and total updates were successful and when they occurred.
  1. Go to the Configuration tab in the Console.
  2. Open the Replication folder and expand the appropriate database.
  3. Select the sync agreement.
  4. In the Summary tab, the status of the latest sync process is shown at the bottom.

16.12. Modifying the Synchronization Agreement

Certain attributes of the sync agreement can be modified, including the connection information. Using the command line, many additional parameters can be created with or added to the sync agreement, including changing the sync interval and setting a sync schedule.

16.12.1. Editing the Synchronization Agreement in the Console

Most of the information which can be edited in the Console is limited to connection information, including the protocol to use and the bind credentials. It is also possible to edit the sync agreement description.
  1. In the Configuration tab, expand the Replication folder.
  2. Expand the database being synced. All of the synchronization agreements are listed below the database. Double-click the sync agreement to open it in the main window.
    Selecting the Synchronization Agreement

    Figure 16.7. Selecting the Synchronization Agreement

  3. Click the Connection tab.
    The Connection tab

    Figure 16.8. The Connection tab

    There are three areas of information that can be edited.
    • The connection type (standard, TLS, and Start TLS).
    • The bind user, both DN and password.
    • Whether to sync new Directory Server users and new Directory Server groups automatically.
    There are three options for the connection type — standard, TLS, and Start TLS — but there are really only two connection protocols, LDAP and LDAPS. Both a standard connection and Start TLS connection use LDAP (Start TLS creates a secure connection over an insecure port).
    It is not possible to change the connection protocol because it is not possible to change the port number used to connect to the Windows sync peer.
    It is possible to change the connection type between the standard connection and Start TLS, but it is not possible to change from TLS to either the standard or Start TLS connections. Likewise, it is not possible to go from standard or Start TLS to TLS. If you need to change the connection protocol or the port number, delete the sync agreement and create a new one.

16.12.2. Adding and Editing the Synchronization Agreement in the Command Line

Creating or editing the sync agreement through the command line is more flexible and provides more options than using the Directory Server Console. The full list of sync agreement attributes are described in the corresponding section in the Red Hat Directory Server Configuration, Command, and File Reference.

16.12.2.1. Creating a Basic Synchronization Agreement

The most basic sync agreement defines the Directory Server database and the Active Directory sync peer:
  • For the Directory Server database:
    • The synchronized subtree in the directory (nsds7DirectoryReplicaSubtree)
    • The Directory Server root DN (nsDS5ReplicaRoot)
  • For the Active Directory domain:
    • The synchronized subtree in the Active Directory domain (nsds7WindowsReplicaSubtree)
    • The Active Directory domain name (nsds7WindowsDomain)
It also defines the connection information that the Directory Server uses to bind to the Active Directory domain:
  • The Active Directory host name, IPv4 address, or IPv6 address (nsDS5ReplicaHost).
  • The Active Directory port (nsDS5ReplicaPort).
  • The type of connection (nsDS5ReplicaTransportInfo), which can be standard (LDAP), TLS (SSL), or StartTLS (TLS), which is a secure connection over a standard port.
  • The user name (nsDS5ReplicaBindDN) and password (nsDS5ReplicaCredentials) for the Directory Server to use to bind to the Active Directory server.
For example, using ldapmodify:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
dn: cn=replication_agreement_name,cn=replica,cn="dc=example,dc=com",cn=mapping tree,cn=config
changetype: add
objectclass: top
objectclass: nsDSWindowsReplicationAgreement
cn: replication_agreement_name
nsds7WindowsReplicaSubtree: cn=Users,dc=ad1
nsds7DirectoryReplicaSubtree: ou=People,dc=example,dc=com
nsds7WindowsDomain: ad1
nsDS5ReplicaRoot: dc=example,dc=com
nsDS5ReplicaHost: ad1.windows-server.com
nsDS5ReplicaPort: 389
nsDS5ReplicaBindDN: cn=sync user,cn=Users,dc=ad1
nsDS5ReplicaCredentials: {DES}ffGad646dT0nnsT8nJOaMA==
nsDS5ReplicaTransportInfo: TLS
nsds7NewWinUserSyncEnabled: on
nsds7NewWinGroupSyncEnabled: on

16.12.2.2. Setting Synchronization Schedules

Synchronization works two ways. The Directory Server sends its updates to Active Directory on a configurable schedule, similar to replication, using the nsds5replicaupdateschedule attribute. The Directory Server polls the Active Directory to check for changes; the frequency that it checks the Active Directory server is set in the winSyncInterval attribute.
By default, the Directory Server update schedule is to always be in sync. The Active Directory interval is to poll the Active Directory every five minutes.
To change the schedule the Directory Server uses to send its updates to the Active Directory, edit the nsds5replicaupdateschedule attribute. The schedule is set with start (SSSS) and end (EEEE) times in the form HHMM, using a 24-hour clock. The days to schedule sync updates are use ranging from 0 (Sunday) to 6 (Saturday).
nsds5replicaupdateschedule: SSSS EEEE DDDDDDD
For example, this schedules synchronization to run from noon to 2:00pm on Sunday, Tuesday, Thursday, and Saturday:
nsds5replicaupdateschedule: 1200 1400 0246

Note

The synchronization times cannot wrap around midnight, so the setting 2300 0100 is not valid.
To change how frequently the Directory Server checks the Active Directory for changes to Active Directory entries, reset the winSyncInterval attribute. This attribute is set in seconds, so the default of 300 means that the Directory Server polls the Active Directory server every 300 seconds, or five minutes. Setting this to a higher value can be useful if the directory searches are taking too long and affecting performance.
winSyncInterval: 1000

16.12.2.3. Changing Synchronization Connections

Two aspects of the connection for the sync agreement can be altered:
  • The bind user name and password (nsDS5ReplicaBindDN and nsDS5ReplicaCredentials).
  • The connection method (nsDS5ReplicaTransportInfo).
    It is only possible to change the nsDS5ReplicaTransportInfo from LDAP to TLS and vice versa. It is not possible to change to or from SSL because it is not possible to change the port number, and switching between LDAP and LDAPS requires changing the port number.
For example:
nsDS5ReplicaBindDN: cn=sync user,cn=Users,dc=ad1
nsDS5ReplicaCredentials: {DES}ffGad646dT0nnsT8nJOaMA==
nsDS5ReplicaTransportInfo: TLS

Warning

It is not possible to change the port number of the Active Directory sync peer. Therefore, it is also not possible to switch between standard/Start TLS connections and TLS connections, since that requires changing between standard and insecure ports.
To change to or from TLS, delete the sync agreement and add it again with the updated port number and new transport information.

16.12.2.4. Handling Entries That Move Out of the Synchronized Subtree

The sync agreement defines what subtrees in both Active Directory and Directory Server are synchronized between each other. Entries within the scope (the subtree) are synchronized; other entries are ignored.
However, the synchronization process actually starts at the root DN to begin evaluating entries for synchronization. Entries are correlated based on the samAccount in the Active Directory and the uid attribute in Directory Server. The synchronization plug-in notes if an entry (based on the samAccount/uid relationship) is removed from the synced subtree either because it is deleted or moved. That is the signal to the synchronization plug-in that the entry is no longer to be synced.
The issue is that the sync process needs some configuration to determine how to handle that moved entry. There are three options: delete the corresponding entry, ignore the entry (the default), or unsync the entry.

Note

These sync actions only relate to how to handle on the Directory Server side when an entry is moved out of scope on the Active Directory side. This does not affect any Active Directory entry if an entry is moved out of the synced subtree on the Directory Server side.
The default behavior in Directory Server 9.0 was to delete the corresponding Directory Server entry. This was true even if the entry on the Active Directory side was never synchronized over to the Directory Server side. Starting in Directory Server 9.1, the default behavior is to ignore the entry and take no action.
For example, a user with the samAccount ID of jsmith was created in the ou=Employees subtree on Active Directory. The synchronized subtree is ou=Users, so the jsmith user was never synchronized over to Directory Server.
Active Directory Tree

Figure 16.9. Active Directory Tree

For 7.x and 8.x versions of Directory Server, synchronization simply ignored that user, since it was outside the synced subtree.
Starting in Directory Server 9.0, Directory Server began supporting subtree renames — which means that existing entries could be moved between branches of the directory tree. The synchronization plug-in, then, assumes that entries in the Active Directory tree which correspond to a Directory Server user (samAccount/uid relationship) but are outside the synced subtree are intentionally moved outside the synced subtree — essentially, a rename operation. The assumption then was that the "corresponding" Directory Server entry should be deleted.
Active Directory and Directory Server Trees Compared

Figure 16.10. Active Directory and Directory Server Trees Compared

This assumption is not necessarily an accurate one, particularly for user entries which always existed outside the synced subtree.
The winSyncMoveAction attribute for the synchronization agreement sets instructions on how to handle these moved entries:
  • none takes no action, so if a synced Directory Server entry exists, it may be synced over to or create an Active Directory entry within scope. If no synced Directory Server entry exists, nothing happens at all (this is the default behavior in the Directory Server version 9.1 and later).
  • unsync removes any sync-related attributes (ntUser or ntGroup) from the Directory Server entry but otherwise leaves the Directory Server entry intact.

    Important

    There is a risk when unsyncing entries that the Active Directory entry may be deleted at a later time, and the Directory Server entry will be left intact. This can create data inconsistency issues, especially if the Directory Server entry is ever used to recreate the entry on the Active Directory side later.
  • delete deletes the corresponding entry on the Directory Server side, regardless of whether it was ever synced with Active Directory (this was the default behavior in 9.0).

    Important

    You almost never want to delete a Directory Server entry without deleting the corresponding Active Directory entry. This option is available only for compatibility with Directory Server 9.0 systems.
If it is necessary to change the default behavior from none, then edit the synchronization agreement to add the winSyncMoveAction attribute. Using ldapmodify:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: cn=replication_agreement_name,cn=replica,cn="dc=example,dc=com",cn=mapping tree,cn=config
changetype: modify
add: winSyncMoveAction
winSyncMoveAction: unsync

16.13. Managing the Password Sync Service

Important

Password Sync must be installed on every domain controller in the Active Directory domain in order to synchronize Windows passwords.
The service synchronizes password changes made on Active Directory with the corresponding entries' passwords on the Directory Server. Like any Windows service, it can be modified, started and stopped, and uninstalled, depending on how synchronization between Directory Server and Active Directory changes.

16.13.1. Modifying Password Sync

To reconfigure Password Sync:
  1. Open Control Panel and select Programs and Features.
  2. Select the Red Hat Directory Password Sync entry, and click the Change button to relaunch the installer to change the settings.
  3. Go back through the configuration screens to make any changes to the configuration.

16.13.2. Starting and Stopping the Password Sync Service

The Password Sync Service is configured to start whenever the Active Directory host is started. To reconfigure the service so that it does not start when Windows reboots:
  1. Open the Services application.
  2. Double-click the Password Synchronization service.
  3. Select the Manual radio button, and click OK.
To start and stop Password Sync:
  1. Open the Services application.
  2. Right-click the Password Synchronization service.
  3. Select Stop, Start, or Restart, and click OK
Changed passwords are captured even if the Password Synchronization service is not running. If Password Synchronization is restarted, the password changes are sent to Directory Server at the next synchronization.

16.13.3. Uninstalling Password Sync Service

  1. Open Control Panel and select Programs and Features.
  2. Select the Red Hat Directory Password Sync entry, and click the Uninstall button.
  3. If TLS was configured for the Password Sync, then the cert8.db and key3.db databases that were created were not removed when Password Sync was uninstalled. Delete these files by manually.

16.13.4. Upgrading Password Sync

For details, see the corresponding section in the Red Hat Directory Server Installation Guide.

16.14. Troubleshooting

If synchronization does not seem to function properly, see the Windows event log or Directory Server error log for information on any potential problems.
Enable replication logging to record synchronization errors

Enable replication logging for more detailed information on synchronization to be recorded in the error logs. The replication log level produces more verbose logs from the sync code. Messages related to synchronization traffic (which is the same as replication traffic) can help in diagnosing problems.

  1. In the Console, click the Configuration tab.
  2. Select Logs from the navigation menu on the right, and open the error log.
  3. Scroll down to error log level, and select Replication from the menu.
  4. Hit save.
Error #1: The message box when creating the sync agreement indicates that the it cannot connect to Active Directory.

Make sure that the directory suffixes, Windows domain and domain host, and the administrator DN and password are correct. Also verify that the port number used for LDAPS is correct. If all of the connection information is correct, make sure that Active Directory machine is running.

Error #2: After synchronization, the status returns error 81.

One of the sync peer servers has not been properly configured for TLS communication. Examine the Directory Server access log file to see if the connection attempt was received by the Directory Server. There are also helpful messages in the Directory Server's error log file.

To narrow down the source of the misconfiguration, try to establish an LDAPS connection to the Directory Server. If this connection attempt fails, check all values (including the port number, host name or IPv4/IPv6 address, search base, and user credentials) to see if any of these are the problem. If all else fails, reconfigure the Directory Server with a new certificate.
If the LDAPS connection to the Directory Server is successful, it is likely that the misconfiguration is on Active Directory. Examine the Windows event log file for error messages.

Note

A common problem is that the certificate authority was not configured as trusted when the Windows sync services certificate database was configured.
Error #3: An entry is moved from one subtree on Active Directory to another subtree, but the user is not moved to the corresponding subtree on Directory Server.

This is a known issue with synchronizing modrdn operations on Active Directory with entries on Directory Server. To work around it, delete the entry on Active Directory and then add it anew to the new subtree. The deletion and the addition will be properly synchronized to the Directory Server peer.



[2] Unlike a consumer, changes can still be made on the un-synced server. Use ACLs to prevent editing or deleting entries on the un-synced server to maintain data integrity.

Chapter 17. Setting up Content Synchronization

Using the Content Synchronization plug-in, Directory Server supports the SyncRepl protocol according to RFC 4533. This protocol enables LDAP servers and clients to use Red Hat Directory Server as a source to synchronize their local database with the changing content of Directory Server.
To use the SyncRepl protocol:
  • Enable the Content Synchronization plug-in in Directory Server and optionally create a new user which the client will use to bind to Directory Server. The account must have permissions to read the content in the directory.
  • Configure the client. For example, set the search base for a subtree to synchronize. For further details, see your client's documentation.
Before clients are able to connect to Directory Server, set up the Content Synchronization plug-in:
  1. The Content Synchronization plug-in requires the Retro Changelog plug-in to log the nsuniqueid attribute:
    1. To verify if the retro changelog is already enabled, enter:
      # ldapsearch -D "cn=Directory Manager" -W -x -b \
           'cn=Retro Changelog Plugin,cn=plugins,cn=config' nsslapd-pluginEnabled
      ...
      dn: cn=Retro Changelog Plugin,cn=plugins,cn=config
      nsslapd-pluginEnabled: off
      If the nsslapd-pluginEnabled attribute is set to off, the retro changelog is disabled. To enable, see Section 15.21.1, “Enabling the Retro Changelog Plug-in”.
    2. Add the nsuniqueid attribute to retro changelog plug-in configuration:
      # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
      
      dn: cn=Retro Changelog Plugin,cn=plugins,cn=config
      changetype: add
      add: nsslapd-attribute
      nsslapd-attribute: nsuniqueid:targetUniqueId
    3. Optionally, apply the following recommendations for improved performance:
      1. Set maximum validity for entries in the retro change log. For example, to set 2 days (2d):
        # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
        
        dn: cn=changelog5,cn=config
        changetype: modify
        replace: nsslapd-changelogmaxage
        nsslapd-changelogmaxage: 2d
      2. If you know which back end or subtree clients access to synchronize data, limit the scope of the Retro Changelog plug-in. For example, to exclude the cn=demo,dc=example,dc=com subtree, enter:
        # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
        
        dn: cn=Retro Changelog Plugin,cn=plugins,cn=config
        changetype: modify
        replace: nsslapd-exclude-suffix
        nsslapd-exclude-suffix: cn=demo,dc=example,dc=com
  2. Enable the Content Synchronization plug-in:
  3. Using the defaults, Directory Server creates an access control instruction (ACI) in the oid=1.3.6.1.4.1.4203.1.9.1.1,cn=features,cn=config entry that enables all users to use the SyncRepl protocol:
    aci: (targetattr != "aci")(version 3.0; acl "Sync Request Control";
       allow( read, search ) userdn = "ldap:///all";)
    Optionally, update the ACI to limit using the SyncRepl control. For further details about ACIs, see Section 18.13, “Defining Bind Rules”.
  4. Restart Directory Server:
    # systemctl restart dirsrv@instance_name
Clients are now able to synchronize data with Directory Server using the SyncRepl protocol.

Chapter 18. Managing Access Control

This chapter describes how you use Access Control Instructions (ACI) in Red Hat Directory Server to manage access to entries.

18.1. Access Control Principles

When Directory Server receives a request, it uses the authentication information provided by the user in the bind operation and the ACIs defined in the directory to allow or deny access to the requested entry or attribute. The server can allow or deny permissions for actions, such as read, write, search, and compare. The permission level granted to a user depends on the authentication information provided.
Access control in Directory Server enables you to set precise rules on when the ACIs are applicable:
  • For the entire directory, a subtree, or specific entries
  • For a specific user, all users belonging to a specific group or role, or all users in the directory
  • For a specific location, such as an IP address, an IP range, or a DNS name.
    Note that load balancers can affect location-specific rules.

Important

Complex ACIs are difficult to read and understand. Instead of one complex ACI in most cases, it is better to write multiple simple rules to achieve the same effect.

18.2. ACI Placement

Directory Server stores ACIs in the multi-valued aci operational attribute in directory entries. To set an ACI, add the aci to the corresponding directory entry. Directory Server applies the ACIs:
  • Only to the entry that contains the ACI, if it does not have any child entries.
    For example, if a client requires access to the uid=user_name,ou=People,dc=example,dc=com object, and an ACI is only set on dc=example,dc=com and not on any child entries, only this ACI is applied.
  • To the entry that contains the ACI and to all entries below it, if it has child entries. As a direct consequence, when the server evaluates access permissions to any given entry, it verifies the ACIs for every entry between the one requested and the directory suffix, as well as the ACIs on the entry itself.
    For example, ACIs are set on the dc=example,dc=com and the ou=People,dc=example,dc=com entry. If a client wants to access the uid=user_name,ou=People,dc=example,dc=com object, which has no ACI set, Directory Server first validates the ACI on the dc=example,dc=com entry. If this ACI grants access, Directory Server then verifies the ACI on ou=People,dc=example,dc=com. If this ACI successfully authorizes the client, they can access the object.

Note

ACIs set in the rootDSE entry apply only to this entry.
An ACI created on an entry can be set not to apply directly to that entry but rather to some or all of the entries in the subtree below. The advantage of this approach is that general ACIs can be placed higher in the directory tree to have effect on entries located lower in the tree. For example, an ACI that targets entries that include the inetOrgPerson object class can be created at the level of an organizationalUnit entry or a locality entry.

Note

Minimize the number of ACIs in the directory tree by placing general rules at high level branch points. To limit the scope of more specific rules, place them to leaf entries as closely as possible.

18.3. ACI Structure

The aci attribute uses the following syntax:
(target_rule) (version 3.0; acl "ACL_name"; permission_rule bind_rules;)

Note

The permission and the bind rule pair are called an access control rule.
To efficiently set multiple access controls for a given target, you can set multiple access control rules for each target:
(target_rule)(version 3.0; acl "ACL_name"; permission_rule bind_rules; permission_rule bind_rules; ... ;)

18.4. ACI Evaluation

To evaluate the access rights to a particular entry, the server creates a list of the ACIs present on the entry itself and on the parent entries back up to the top level entry stored on the Directory Server. ACIs are evaluated across all databases for a particular instance but not across different instances.
Directory Server evaluates this list of ACIs based on the semantics of the ACIs, not on their placement in the directory tree. This means that ACIs that are close to the root of the directory tree do not take precedence over ACIs that are closer to the leaves of the directory tree.
In Directory Server, the deny permission in ACIs take precedence over the allow permission. For example, if you deny write permission at the directory's root level, none of the users can write to the directory, regardless if an other ACI grants this permission. To grant a specific user write permissions to the directory, you have to add an exception to the original denying rule to allow the user to write in that directory.

Note

For improved ACIs, use fine-grained allow rules instead of deny rules.

18.5. Limitations of ACIs

When you set ACIs, the following restrictions apply:
  • If your directory database is distributed over multiple servers, the following restrictions apply to the keywords you can use in ACIs:
    • ACIs depending on group entries using the groupdn keyword must be located on the same server as the group entry.
      If the group is dynamic, all members of the group must have an entry on the server. Member entries of static groups can be located on the remote server.
    • ACIs depending on role definitions using the roledn keyword, must be located on the same server as the role definition entry. Every entry that is intended to have the role must also be located on the same server.
    However, you can match values stored in the target entry with values stored in the entry of the bind user by, for example, using the userattr keyword. In this case, access is evaluated normally even if the bind user does not have an entry on the server that stores the ACI.
  • You cannot use virtual attributes, such as Class of Service (CoS) attributes, in the following ACI keywords:
    • targetfilter
    • targetattrfilters
    • userattr
  • Access control rules are evaluated only on the local server. For example, if you specify the host name of a server in LDAP URLs in ACI keywords, the URL will be ignored.

18.6. How Directory Server Handles ACIs in a Replication Topology

ACIs are stored in aci attributes of entries. Therefore, if an entry containing ACIs is part of a replicated database, the ACIs are replicated.
ACIs are always evaluated on server that resolves the incoming LDAP requests. When a consumer server receives an update request, it returns a referral to the supplier server before evaluating whether the request can be serviced on the supplier.

18.7. Displaying ACIs

This section describes how to display ACIs.

18.7.1. Displaying ACIs Using the Command Line

Use the ldapsearch utility to display ACI using the command line. For example, to display the ACIs set on dc=example,dc=com and sub-entries:
# ldapsearch -D "cn=Directory Manager" -W -p 389 -h server.example.com -x \
     -b "dc=example,dc=com" -s sub '(aci=*)' aci

18.7.2. Displaying ACIs Using the Console

To display ACIs using the Console:
  1. Open the Directory Server Console.
  2. On the Directory tab, right-click the entry, and select Set Access Permissions
  3. Optionally, select Show Inherited ACIs to additionally display entries on higher levels of the directory.

18.8. Adding an ACI

This section describes how you can add an ACI.

18.8.1. Adding an ACI Using the Command Line

Use the ldapmodify utility to add an ACI. For example:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
dn: ou=People,dc=example,dc=com
changetype: modify
add: aci
aci: (targetattr="userPassword") (version 3.0; acl "Allow users updating their password";
 allow (write) userdn= "ldap:///self";)

18.8.2. Adding an ACI Using the Console

To use the console to add an ACI:
  1. Open the Directory Server Console.
  2. On the Directory tab, right-click the entry, and select Set Access Permissions
  3. Enter the name of the ACI into the ACI Name field.
  4. On the Users tab, optionally add users, groups, roles, administrators, or special rights to the list by clicking the Add button:
    1. Enter a string into the Search for field, select a search area, and click Search.
    2. Select the entry from the search results and click Add.
    3. Click OK.
  5. On the Rights tab, select the permissions to set in this ACI.
  6. On the Targets tab, select the target directory entry.

    Note

    You can change the value of the target DN, but the new DN must be a direct or indirect child of the selected entry.
    If you do not want ACIs to target every entry in the sub-tree under this node, enter a filter in the Filter for Sub-entries field. The filter applies to every entry below the target entry. For example, setting the filter to ou=Sales means that only entries with ou=Sales in their DN are returned.
    Additionally, you can restrict the scope of the ACI to certain attributes by selecting the attributes in the list.
  7. On the Hosts tab, optionally add a DNS name or IP address.
    If you set a DNS name or IP address, the ACI applies only to LDAP operations from these hosts.
  8. On the Times tab, optionally select at which times the ACI will be applied.
    By default, access is allowed at all times. Change the access times by clicking and dragging the cursor over the table. Note that you can only select continuous time ranges.
  9. Click OK.

Note

At any point of creating an ACI, click the Edit Manually button to display the LDIF statement corresponding to the wizard input. You can edit this statement in this window, however, the changes may not be visible in the graphical interface.

18.9. Deleting an ACI

This section describes how you can delete an ACI from an entry.

18.9.1. Deleting an ACI Using the Command Line

To delete an ACI using the command line:
  1. Display the ACIs set on the entry. See Section 18.7.1, “Displaying ACIs Using the Command Line”.
  2. Delete the ACI:
    • If only one aci attribute is set on the entry or you want to remove all ACIs from the entry:
      # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
      dn: ou=People,dc=example,dc=com
      changetype: delete
      delete: aci
    • If multiple ACIs exist on the entry and you want to delete a specific ACI, specify the exact ACI:
      # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
      dn: ou=People,dc=example,dc=com
      changetype: modify
      delete: aci
      aci: (targetattr="userPassword") (version 3.0; acl "Allow users
       updating their password"; allow (write) userdn= "ldap:///self";)
For further details about deleting attributes, see Section 3.1.4.3, “Deleting Attributes from an Entry”.

18.9.2. Removing an ACI Using the Console

To remove an ACI using the Console:
  1. Open the Directory Server Console.
  2. On the Directory tab, right-click the entry, and select Set Access Permissions
  3. Select the ACI from the list and click Remove.
  4. Click OK.

18.10. Updating an ACI

This section describes how you can update an existing ACI.

18.10.1. Updating an ACI Using the Command Line

To update an ACI using the command line:

18.10.2. Updating an ACI Using the Console

To update an ACI using the Console:
  1. Open the Directory Server Console.
  2. On the Directory tab, right-click the entry, and select Set Access Permissions
  3. Select the ACI from the list and click Edit.
  4. Update the ACI. The individual screens are described in the Section 18.8.2, “Adding an ACI Using the Console” section.
  5. Click OK.

18.11. Defining Targets

Target rules in an ACI define to which entries Directory Server applies the ACI. If you do not set a target, the ACI applies to the entry containing the aci attribute and to entries below.
In an ACI, the following highlighted part is the target rule:
(target_rule)(version 3.0; acl "ACL_name"; permission_rule bind_rules;)
For complex ACIs, Directory Server supports multiple target rules in an ACI:
(target_rule_1)(target_rule_2)(...)(version 3.0; acl "ACL_name"; permission_rule bind_rules;)
If you specify multiple target rules, the order is not relevant.

Syntax

The general syntax of a target rule is:
(keyword comparison_operator "expression")
  • keyword: Sets the type of the target. See Section 18.11.1, “Frequently Used Target Keywords”.
  • comparisonoperator: Valid values are = and != and indicate whether or not the target is the object specified in the expression.

    Warning

    For security reasons, Red Hat recommends not using the != operator, because it allows the specified operation on all other entries or attributes. For example:
    (targetattr != "userPassword");(version 3.0; acl "example"); allow (write) ... );
    The previous example allows users to set, update, or delete any attribute except the userPassword attribute under the Distinguished Name (DN) you set the ACI. However, this enables users, for example, to add an additional aci attribute that allows write access to this attribute as well.
  • expression: Sets the target and must be surrounded by quotation marks. The expression itself depends on the keyword you use.

18.11.1. Frequently Used Target Keywords

Administrators frequently use the following target keywords:

18.11.1.1. Targeting a Directory Entry

To control access based on a DN and the entries below it, use the target keyword in the ACI. A target rule which uses the target keyword takes a DN as expression:
(target comparison_operator "ldap:///distinguished_name")

Note

You must set the ACI with the target keyword on the DN you are targeting or a higher-level DN of it. For example, if you target ou=People,dc=example,dc=com, you must either set the ACI on ou=People,dc=example,dc=com or dc=example,dc=com.

Example 18.1. Using the target Keyword

To enable users that are stored in the ou=People,dc=example,dc=com entry to search and display all attributes in their own entry:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
dn: dc=People,dc=example,dc=com
changetype: modify
add: aci
aci: (target = "ldap:///ou=People,dc=example,dc=com") (version 3.0;
 acl "Allow users to read and search attributes of own entry"; allow (search, read)
 (userdn = "userdn = "ldap:///self");)

Using Wildcards with the target Keyword

You can use the * wildcard character target multiple entries.
The following target rule example matches all entries in ou=People,dc=example,dc=com whose uid attribute is set to a value that starts with the letter a:
(target = "ldap:///uid=a*,ou=People,dc=example,dc=com")
Depending on the position of the wildcard, the rule not only applies to attribute values, but also to the full DN. Therefore, you can uses the wildcard as a substitute for portions of the DN.

Example 18.2. Targeting a Directory Entries Using Wildcards

The following rule targets all entries in the dc=example,dc=com tree with a matching uid attribute and not only entries which are stored in the dc=example,dc=com entry itself:
(target = "ldap:///uid=user_name*,dc=example,dc=com")
The previous target rule matches multiple entries, such as:
  • uid=user_name,dc=example,dc=com
  • uid=user_name,ou=People,dc=example,dc=com
  • uid=user_name2,dc=example,dc=com

Important

Directory Server does not support wildcards in the suffix part of a DN. For example, if your directory's suffix is dc=example,dc=com, you cannot use a target with a wildcard in this suffix, such as (target = "ldap:///dc=*.com").

18.11.1.2. Targeting Attributes

To limit access in an ACI to certain attributes, use the targetattr keyword. For example, this keyword defines:
  • In a read operation, what attributes will be returned to a client
  • In a search operation, what attributes will be searched
  • In a write operation, what attributes can be written to an object
  • In an add operation, what attributes can be added when creating a new object

Note

In certain situations, you can use the targetattr keyword to secure ACIs by combining other target keywords with targetattr. See Section 18.11.3, “Advanced Usage of Target Rules” for examples.
To separate multiple attributes in a target rule that uses the targetattr keyword, use || command:
(targetattr comparison_operator "attribute_1 || attribute_2 || ...")
The attributes set in the expression must be defined in the schema.

Note

The attributes specified in the expression applies to the entry on which you create the ACI and to all entries below it.

Example 18.3. Using the targetattr Keyword

To enable users stored in dc=example,dc=com and all subentries to update the userPassword attribute in their own entry:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
dn: dc=example,dc=com
changetype: modify
add: aci
aci: (targetattr = "userPassword") (version 3.0;
 acl "Allow users updating own userPassword";
 allow (write) (userdn = "ldap:///self");)

Using Wildcards with the targetattr Keyword

Using the * wildcard character, you can, for example, target all attributes:
(targetattr = "*")

Warning

For security reasons, do not use wildcards with the targetattr, because it allows access to all attributes, including operational attributes. For example, if users can add or modify all attributes, users might create additional ACI and increase their own permissions.

18.11.1.3. Targeting Entries and Attributes Using LDAP Filters

To target a group of entries that match a certain criteria, use the targetfilter keyword with an LDAP filter:
(targetfilter comparison_operator "LDAP_filter")
The filter expression is a standard LDAP search filter, as described in Chapter 14, Finding Directory Entries.

Example 18.4. Using the targetfilter Keyword

To grant permissions to members of the cn=Human Resources,dc=example,dc.com group to modify all entries having the department attribute set to Engineering or Sales:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
dn: dc=example,dc=com
changetype: modify
add: aci
aci: (targetfilter = "(|(department=Engineering)(department=Sales)")
 (version 3.0; acl "Allow HR updating engineering and sales entries";
 allow (write) (groupdn = "ldap:///cn=Human Resources,dc=example,dc.com");)
The targetfilter keyword targets whole entries. If you combine it with the targetattr keyword, the ACI applies only to a subset of attributes of the targeted entries. See Section 18.11.3.3, “Targeting Certain Attributes of Entries Matching a Filter”.

Note

Using LDAP filters is useful when targeting entries and attributes that are spread across the directory. However, the results are sometimes unpredictable because filters do not directly name the object for which you are managing access. The set of entries targeted by a filtered ACI is likely to change as attributes are added or deleted. Therefore, if you use LDAP filters in ACIs, verify that they target the correct entries and attributes by using the same filter, for example, in an ldapsearch operation.

Using Wildcards with the targetfilter Keyword

The targetfilter keyword supports wildcards similarly to standard LDAP filters. For example, to target all uid attributes whose value starts with adm:
(targetattr = "(uid=adm*) ...)

18.11.1.4. Targeting Attribute Values Using LDAP Filters

You can use access control to target specific values of attributes. This means that you can grant or deny permissions on an attribute if that attribute's value meets the criteria that is defined in the ACI. An ACI that grants or denies access based on an attribute's value is called a value-based ACI.
To create a value-based ACI, use the targetattrfilters keyword with the following syntax:
  • For one operation with one attribute and filter combination:
    (targetattrfilters="operation=attribute:filter")
  • For one operation with multiple attribute and filter combinations:
    (targetattrfilters="operation=attribute_1:filter_1 && attribute_2:filter_2 ... && attribute_m:filter_m")
  • For two operations, each with multiple attribute and filter combinations:
    (targetattrfilters="operation_1=attribute_1_1:filter_1_1 && attribute_1_2:filter_1_2 ... && attribute_1_m:filter_1_m , operation_2=attribute_2_1:filter_2_1 && attribute_2_2:filter_2_2 ... & attribute_2_n:filter_2_n ")
In the previous syntax examples, you can set the operations either to add or del. The attribute:filter combination sets the filter and the attribute the filter is applied to.

Note

Value-based ACIs are only supported using the command line.
The following describes how filter must match:
  • When creating an entry and a filter applies to an attribute in the new entry, then each instance of that attribute must match the filter.
  • When deleting an entry and a filter applies to an attribute in the entry, then each instance of that attribute must also match the filter.
  • When modifying an entry and the operation adds an attribute, then the add filter that applies to that attribute must match.
  • If the operation deletes an attribute, then the del filter that applies to that attribute must match. If the individual values of an attribute already present in the entry are replaced, then both the add and del filters must match.

Example 18.5. Using the targetattrfilters Keyword

To create an ACI that enables users to add any role to their own entry, except the Admin role, and to add the telephone attribute, as long as the value begins with the 123 prefix:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
dn: dc=example,dc=com
changetype: modify
add: aci
aci: (targetattrfilters="add=nsroledn:(!(nsroledn=cn=Admin)) &&
 telephoneNumber:(telephoneNumber=123*)") (version 3.0;
 acl "Allow adding roles and telephone";
 allow (add) (userdn = "ldap:///self");)

18.11.2. Further Target Keywords

This section describes target keywords that are less-frequently used.

18.11.2.1. Targeting Source and Destination DNs

In certain situations, administrators want to allow users to move directory entries. Using the target_from and target_to keywords in an ACI, you can specify the source and destination of the operation, however, without enabling the user:
  • To move entries from a different source as set in the ACI.
  • To move entries to a different destination as set in the ACI.
  • To delete existing entries from the source DN.
  • To add new entries to the destination DN.

Example 18.6. Using the target_from and target_to Keywords

For example, to enable the uid=user,dc=example,dc=com account to move user accounts from the cn=staging,dc=example,dc=com entry to cn=people,dc=example,dc=com:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
dn: dc=example,dc=com
changetype: modify
add: aci
aci: (target_from="ldap:///uid=*,cn=staging,dc=example,dc=com")
 (target_to="ldap:///cn=People,dc=example,dc=com")
 (version 3.0; acl "MODDN from"; allow (moddn))
 userdn="ldap:///uid=user,dc=example,dc=com";)

Note

ACIs apply only to the subtree where they are defined. In the previous example, the ACI is applies only to the dc=example,dc=com subtree.
If the target_from or target_to keyword is not set, the ACI matches any source or destination.

18.11.3. Advanced Usage of Target Rules

By combining multiple keywords, you can create complex target rules. This section provides examples of the advanced usage of target rules.

18.11.3.1. Delegating Permissions to Create and Maintain Groups

In certain situations, administrators want to delegate permissions to other accounts or groups. By combining target keywords, you can create secure ACIs that solve this request.

Example 18.7. Delegating Permissions to Create and Maintain Groups

To enable the uid=user,ou=People,dc=example,dc=com" account to create and update groups in the ou=groups,dc=example,dc=com entry:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
dn: dc=example,dc=com
changetype: modify
add: aci
aci: (target = "ldap:///cn=*,ou=Groups,dc=example,dc=com")
 targetfilter="(&(objectClass=top)(objectClass=groupOfUniqueNames))")
 (targetattr="cn || uniqueMember || objectClass")
 (version 3.0; acl "example"; allow (read, search, write, add)
 (userdn = "ldap:///uid=test,ou=People,dc=example,dc=com");)
For security reasons, the previous example adds certain limitations. The uid=test,ou=People,dc=example,dc=com user:
  • Can create objects that must contain the top and groupOfUniqueNames object classes.
  • Cannot add additional object classes, such as account. For example, this prevents if you use Directory Server accounts for local authentication, to create new users with an invalid user ID, such as 0 for the root user.

18.11.3.2. Targeting Both an Entry and Attributes

The target controls access based on a DN. However, if you use it in combination with a wildcard and the targetattr keyword, you can target both entries and attributes.

Example 18.8. Targeting Both an Entry and Attributes

To enable the uid=user,ou=People,dc=example,dc.com user to read and search members of groups in all organizational units in the dc=example,dc=com subtree:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
dn: dc=example,dc=com
changetype: modify
add: aci
aci: (target="ldap:///cn=*,dc=example,dc=com")(targetattr="member" || "cn") (version 3.0;
 acl "Allow uid=user to search and read members of groups";
 allow (read, search) (userdn = "ldap:///uid=user,ou=People,dc=example,dc.com");)

18.11.3.3. Targeting Certain Attributes of Entries Matching a Filter

If you combine the targetattr and targetfilter keywords in two target rules, you can target certain attributes in entries that match a filter.

Example 18.9. Targeting Certain Attributes of Entries Matching a Filter

To allow members of the cn=Engineering Admins,dc=example,dc=com group to modify the jpegPhoto and manager attributes of all entries having the department attribute set to Engineering:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
dn: dc=example,dc=com
changetype: modify
add: aci
aci: (targetattr = "jpegPhoto|| manager")
 (targetfilter = "(department=Engineering)") (version 3.0;
 acl "Allow engineering admins updating jpegPhoto and manager of department members";
 allow (write) (groupdn = "ldap:///cn=Engineering Admins,dc=example,dc.com");)

18.11.3.4. Targeting a Single Directory Entry

To target a single directory entry, combine the targetattr and targetfilter keywords.

Example 18.10. Targeting a Single Directory Entry

To enable the uid=user,ou=People,dc=example,dc=com user to read and search the ou and cn attributes in the ou=Engineering,dc=example,dc=com entry:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
dn: ou=Engineering,dc=example,dc=com
changetype: modify
add: aci
aci: (targetattr = "ou || cn")
 (targetfilter = "(ou=Engineering)") (version 3.0;
 acl "Allow uid=user to search and read engineering attributes";
 allow (read, search) (userdn = "ldap:///uid=user,ou=People,dc=example,dc.com");)
To enable the previous example to target only the ou=Engineering,dc=example,dc=com entry, sub-entries in ou=Engineering,dc=example,dc=com must not have the ou attribute set to Engineering.

Important

These kind of ACIs can fail if the structure of your directory changes.
Alternatively, you can create a bind rule that matches the user input in the bind request with an attribute value that is stored in the targeted entry. See Section 18.13.2.1, “Defining Access Based on Value Matching”.

18.12. Defining Permissions

Permission rules define the rights that are associated with the ACI and whether access is allowed or denied.
In an ACI, the following highlighted part is the permission rule:
(target_rule) (version 3.0; acl "ACL_name"; permission_rule bind_rules;)

Syntax

The general syntax of a permission rule is:
permission (rights)

Example 18.11. Defining Permissions

To enable users stored in the ou=People,dc=example,dc=com entry to search and display all attributes in their own entry:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
dn: dc=People,dc=example,dc=com
changetype: modify
add: aci
aci: (target = "ldap:///ou=People,dc=example,dc=com") (version 3.0;
 acl "Allow users to read and search attributes of own entry"; allow (search, read)
 (userdn = "userdn = "ldap:///self");)

18.12.1. User rights

The rights in a permission rule define what operations are granted or denied. In an ACI, you can set one or multiple of the following rights:

Table 18.1. User Rights

Right Description
read Sets whether users can read directory data. This permission applies only to search operations in LDAP.
write Sets whether users can modify an entry by adding, modifying, or deleting attributes. This permission applies to the modify and modrdn operations in LDAP.
add Sets whether users can create an entry. This permission applies only to the add operation in LDAP.
delete Sets whether users can delete an entry. This permission applies only to the delete operation in LDAP.
search Sets whether users can search for directory data. To view data returned as part of a search result, assign search and read rights. This permission applies only to search operations in LDAP.
compare Sets whether the users can compare data they supply with data stored in the directory. With compare rights, the directory returns a success or failure message in response to an inquiry, but the user cannot see the value of the entry or attribute. This permission applies only to the compare operation in LDAP.
selfwrite Sets whether users can add or delete their own DN from a group. This right is used only for group management.
proxy
Sets whether the specified DN can access the target with the rights of another entry. The proxy right is granted within the scope of the ACL, and the user or group who as the right granted can run commands as any Directory Server user. You cannot restrict the proxy rights to certain users.
For security reasons, set ACIs that use the proxy right at the most targeted level of the directory.
all Sets all of the rights, except proxy.

18.12.2. Rights Required for LDAP Operations

This section describes the rights you must grant to users depending on the type of LDAP operation you want to authorize them to perform.
  • Adding an entry:
    • Grant add permission on the entry that you want to add.
    • Grant write permission on the value of each attribute in the entry. This right is granted by default but can be restricted using the targetattrfilters keyword.
  • Deleting an entry:
    • Grant delete permission on the entry that you want to delete.
    • Grant write permission on the value of each attribute in the entry. This right is granted by default but can be restricted using the targetattrfilters keyword.
  • Modifying an attribute in an entry:
    • Grant write permission on the attribute type.
    • Grant write permission on the value of each attribute type. This right is granted by default but can be restricted using the targetattrfilters keyword.
  • Modifying the RDN of an entry:
    • Grant write permission on the entry.
    • Grant write permission on the attribute type that is used in the new RDN.
    • Grant write permission on the attribute type that is used in the old RDN, if you want to grant the right to delete the old RDN.
    • Grant write permission on the value of attribute type that is used in the new RDN. This right is granted by default but can be restricted using the targetattrfilters keyword.
  • Comparing the value of an attribute:
    • Grant compare permission on the attribute type.
  • Searching for entries:
    • Grant search permission on each attribute type used in the search filter.
    • Grant read permission on attribute types used in the entry.

18.12.3. Access Control and the modrdn Operation

To explicitly deny modrdn operations using ACIs, target the relevant entries but omit the targetattr keyword. For example, to add an ACI that defines the cn=example,ou=Groups,dc=example,dc=com group, cannot rename entries in ou=people,dc=example,dc=com which contain the cn attribute:
ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
dn: dc=example,dc=com
changetype: modify
add: aci
aci: (target="ldap:///cn=*,ou=people,dc=example,dc=com")
 (version 3.0; acl "Deny modrdn rights to the example group";
 deny(write) groupdn="ldap:///cn=example,ou=groups,dc=example,dc=com";)

18.13. Defining Bind Rules

The bind rules in an ACI define the required bind parameters that must meet so that Directory Server applies the ACI. For example, you can set bind rules based on:
  • DNs
  • Group memberships or assigned roles
  • Locations from which an entry must bind
  • Types of authentication that must be in use during the bind
  • Times or days on which the bind occurs
In an ACI, the following highlighted part is the bind rule:
(target_rule) (version 3.0; acl "ACL_name"; permission_rule bind_rules;)

Syntax

The general syntax of a bind rule is:
keyword comparison_operator "expression"
  • keyword: Sets the type of the bind operation. See Section 18.13.1, “Frequently Used Bind Rules”.
  • comparison_operator: Valid values are = and != and indicate whether or not the target is the object specified in the expression. If a keyword supports additional comparison operators, it is mentioned in the corresponding section.
  • expression: Sets the expression and must be surrounded by quotation marks. The expression itself depends on the keyword you use.

18.13.1. Frequently Used Bind Rules

Administrators frequently use the following bind keywords:
Additionally, bind rules are frequently combined using Boolean operators. For details, see Section 18.13.3, “Combining Bind Rules Using Boolean Operators”.

18.13.1.1. Defining User-based Access

The userdn keyword enables you to grant or deny access based on one or multiple DNs and uses the following syntax:
userdn comparison_operator "ldap:///distinguished_name || ldap:///distinguished_name || ..."
Set the DN in the expression to:

Note

Do not specify a host name or port number within the LDAP URL. The URL always applies to the local server.
18.13.1.1.1. Using a DN with the userdn Keyword
Set the userdn keyword to a DN to apply the ACI only to the matching entry. To match multiple entries, use the * wildcard in the DN.
Using the userdn keyword with a DN must match the following syntax:
userdn comparison_operator ldap:///distinguished_name

Example 18.12. Using a DN with the userdn Keyword

To enable the uid=admin,ou=People,dc=example,dc=com user to read the manager attribute of all other users in the ou=People,dc=example,dc=com entry:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
dn: ou=People,dc=example,dc=com
changetype: modify
add: aci
aci: (targetattr="manager") (version 3.0; acl "Allow uid=admin reading manager attribute";
 allow (search, read) userdn = "ldap:///uid=admin,ou=People,dc=example,dc=com";)
18.13.1.1.2. Using the userdn Keyword with an LDAP filter
If you want to dynamically allow or deny permissions to users, use the userdn keyword with an LDAP filter:
userdn comparison_operator "ldap:///distinguished_name??scope?(filter)"

Note

The LDAP filter supports the * wildcard.

Example 18.13. Using the userdn Keyword with an LDAP filter

To enable users who have the department attribute set to Human Resources to update the homePostalAddress attribute of users in the ou=People,dc=example,dc=com entry:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
dn: ou=People,dc=example,dc=com
changetype: modify
add: aci
aci: (targetattr="homePostalAddress") (version 3.0;
 acl "Allow HR setting homePostalAddress"; allow (write)
 userdn = "ldap:///ou=People,dc=example,dc=com??sub?(department=Human Resources)";)
18.13.1.1.3. Granting Anonymous Access
In certain situations, administrators want to configure anonymous access to data in the directory. Anonymous access means that it is possible to bind to the directory by providing:
  • No bind DN and password
  • A valid bind DN and password
To configure anonymous access, use the ldap:///anyone expression with the userdn keyword in a bind rule:
userdn comparison_operator "ldap:///anyone"

Example 18.14. Granting Anonymous Access

To enable anyone without authentication to read and search the sn, givenName, and telephoneNumber attributes in the ou=People,dc=example,dc=com entry:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
dn: ou=People,dc=example,dc=com
changetype: modify
add: aci
aci: (targetattr="sn" || targetattr="givenName" || targetattr = "telephoneNumber")
 (version 3.0; acl "Anonymous read, search for names and phone numbers";
 allow (read, search) userdn = "ldap:///anyone")
18.13.1.1.4. Granting Access to Authenticated Users
In certain situations, administrators want to grant permission to any user who is able to successfully bind to Directory Server, except anonymous binds. To configure this feature, use the ldap:///all expression with the userdn keyword in a bind rule:
userdn comparison_operator "ldap:///all"

Example 18.15. Granting Access to Authenticated Users

To enable authenticated users to add and remove themselves as a member from the ou=example,ou=groups,dc=example,dc=com group:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
dn: ou=example,ou=Groups,dc=example,dc=com
changetype: modify
add: aci
aci: (targetattr="member") (version 3.0;
 acl "Allow users to add/remove themselves from example group";
 allow (selfwrite) userdn = "ldap:///all")
18.13.1.1.5. Enabling Users to Access Their Own Entries
To set ACIs which allow or deny access to users to their own entry, use the ldap:///self expression with the userdn keyword in a bind rule:
userdn comparison_operator "ldap:///self"

Example 18.16. Enabling Users to Access Their Own Entries

To enable users in the ou=People,dc=example,dc=com entry to update their own userPassword attribute:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
dn: ou=People,dc=example,dc=com
changetype: modify
add: aci
aci: (targetattr="userPassword") (version 3.0;
 acl "Allow users updating their password";
 allow (write) userdn = "ldap:///self")
18.13.1.1.6. Setting Access for Child Entries of a User
To specify that users are granted or denied access to an entry only if their bind DN is the parent of the targeted entry, use the self:///parent expression with the userdn keyword in a bind rule:
userdn comparison_operator "ldap:///parent"

Example 18.17. Setting Access for Child Entries of a User

To enable the cn=user,ou=People,dc=example,dc=com user to update the manager attribute of its own sub-entries, such as cn=example,cn=user,ou=People,dc=example,dc=com:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
dn: cn=user,ou=People,dc=example,dc=com
changetype: modify
add: aci
aci: (targetattr="manager") (version 3.0;
 acl "Allow cn=user to update manager attributes";
 allow (write) userdn = "ldap:///parent")

18.13.1.2. Defining Group-based Access

Group-based ACIs enable you to manage access by adding or removing users to or from a group. To configure an ACI that is based on a group membership, use the groupdn keyword. If the user is a member of one or multiple of the specified groups, the ACI matches.
When using the groupdn keyword, Directory Server verifies the group membership based on the following attributes:
  • member
  • uniqueMember
  • memberURL
  • memberCertificateDescription
Bind rules with the groupdn keyword use the following syntax:
groupdn comparison_operator "ldap:///distinguished_name || ldap:///distinguished_name || ..."
Set the DN in the expression to:
If you set multiple DNs in one bind rule, Directory Server applies the ACI if the authenticated user is a member of one of these groups. To set the user as a member of multiple groups, use multiple groupdn keywords and combine them using the Boolean and operator. For details, see Section 18.13.3, “Combining Bind Rules Using Boolean Operators”.

Note

Do not specify a host name or port number within the LDAP URL. The URL always applies to the local server.
18.13.1.2.1. Using a DN with the groupdn Keyword
To apply an ACI to members of a group, set the groupdn keyword to the group's DN.
The groupdn keyword set to a DN uses the following syntax:
groupdn comparison_operator ldap:///distinguished_name

Example 18.18. Using a DN with the groupdn Keyword

To enable members of the cn=example,ou=Groups,dc=example,dc=com group to search and read the manager attribute of entries in ou=People,dc=example,dc=com:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
dn: ou=People,dc=example,dc=com
changetype: modify
add: aci
aci: (targetattr="manager") (version 3.0;
 acl "Allow example group to read manager attribute";
 allow (search, read) groupdn = "ldap:///cn=example,ou=Groups,dc=example,dc=com";)
18.13.1.2.2. Using The groupdn Keyword with an LDAP Filter
Using an LDAP filter with the groupdn keyword, you can define that the authenticated user must be a member of at least one of the groups that the filter search returns, to match the ACI.
The groupdn keyword with an LDAP filter uses the following syntax:
groupdn comparison_operator "ldap:///distinguished_name??scope?(filter)"

Note

The LDAP filter supports the * wildcard.

Example 18.19. Using The groupdn Keyword with an LDAP Filter

To enable members of groups in dc=example,dc=com and subtrees, which have the manager attribute set to example, update the homePostalAddress of entries in ou=People,dc=example,dc=com:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
dn: ou=People,dc=example,dc=com
changetype: modify
add: aci
aci: (targetattr="homePostalAddress") (version 3.0;
 acl "Allow manager=example setting homePostalAddress"; allow (write)
 userdn = "ldap:///dc=example,dc=com??sub?(manager=example)";)

18.13.2. Further Bind Rules

This section describes bind rules that are less-frequently used.

18.13.2.1. Defining Access Based on Value Matching

Use the userattr keyword in a bind rule to specify which attribute must match between the entry used to bind to the directory and the targeted entry.
The userattr keyword uses the following syntax:
userattr comparison_operator "attribute_name#bind_type_or_attribute_value
For further details, see:

Important

By default, Directory Server evaluates access rights on the entry they are created. However, to prevent user objects on the same level, Directory Server does not grant add permissions to the entry where you set the ACI, when using the userattr keyword. To configure this behavior, use the userattr keyword in conjunction with the parent keyword and grant the permission additionally on level 0.
18.13.2.1.1. Using the USERDN Bind Type
To apply an ACI when the binding user DN matches the DN stored in an attribute, use the USERDN bind type.
The userattr keyword with the USERDN bind type requires the following syntax:
userattr comparison_operator "attribute_name#USERDN"

Example 18.20. Using the USERDN Bind Type

To grant a manager all permissions to the telephoneNumber attribute of its own associates:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
dn: ou=People,dc=example,dc=com
changetype: modify
add: aci
aci: (targetattr = "telephoneNumber")
 (version 3.0; acl "Manager: telephoneNumber";
 allow (all) userattr = "manager#USERDN";)
The previous ACI is evaluated to be true if the DN of the user who performs the operation on an entry in ou=People,dc=example,dc=com, matches the DN stored in the manager attribute of this entry.
18.13.2.1.2. Using the GROUPDN Bind Type
To apply an ACI when the binding user DN is a member of a group set in an attribute, use the GROUPDN bind type.
The userattr keyword with the GROUPDN bind type requires the following syntax:
userattr comparison_operator "attribute_name#GROUPDN"

Example 18.21. Using the GROUPDN Bind Type

To grant users the permission to delete a group entry which they own under the ou=Social Committee,ou=Groups,dc=example,dc=com entry:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
dn: ou=Social Committee,ou=Groups,dc=example,dc=com
changetype: modify
add: aci
aci: (target="ou=Social Committee,ou=Groups,dc=example,dc=com)
 (targetattrfilters="del=objectClass:(objectClass=groupOfNames)")
 (version 3.0; acl "Delete Group";
 allow (delete) userattr = "owner#GROUPDN";)
The previous ACI is evaluated to be true if the DN of the user who performs the operation is a member of the group specified in the owner attribute.
The specified group can be a dynamic group, and the DN of the group can be under any suffix in the database. However, the evaluation of this type of ACI by the server is very resource-intensive.
If you are using static groups that are under the same suffix as the targeted entry, use the following expression for better performance:
userattr comparison_operator "ldap:///distinguished_name?attribute_name#GROUPDN"
18.13.2.1.3. Using the ROLEDN Bind Type
To apply an ACI when the binding user belongs to a role specified in an attribute, use the ROLEDN bind type.
The userattr keyword with the ROLEDN bind type requires the following syntax:
userattr comparison_operator "attribute_name#ROLEDN"

Example 18.22. Using the ROLEDN Bind Type

To enable users with the cn=Administrators,dc=example,dc=com role to search and read the manager attribute of entries in ou=People,dc=example,dc=com:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
dn: ou=People,dc=example,dc=com
changetype: modify
add: aci
aci: (version 3.0; acl "Allow example role owners to read manager attribute";
 allow (search, read) roledn="ldap:///cn=Administrators,dc=example,dc=com";)
The specified role can be under any suffix in the database. If you are also using filtered roles, the evaluation of this type of ACI uses a lot of resources on the server.
If you are using a static role definition and the role entry is under the same suffix as the targeted entry, use the following expression for better performance:
userattr comparison_operator "ldap:///distinguished_name?attribute_name#ROLEDN"
18.13.2.1.4. Using the SELFDN Bind Type
The SELFDN bind type enables you to grant permissions, when the bound user's DN is set in a single-value attribute of the entry.
The userattr keyword with the SELFDN bind type requires the following syntax:
userattr comparison_operator "attribute_name#SELFDN"

Example 18.23. Using the SELFDN Bind Type

To enable a user to add ipatokenuniqueid=*,cn=otp,dc=example,dc=com entries that have the bind user's DN set in the ipatokenOwner attribute:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
dn: ou=otp,dc=example,dc=com
changetype: modify
add: aci
aci: (target = "ldap:///ipatokenuniqueid=*,cn=otp,dc=example,dc=com")
 (targetfilter = "(objectClass=ipaToken)")(version 3.0;
 acl "token-add-delete"; allow (add) userattr = "ipatokenOwner#SELFDN";)
18.13.2.1.5. Using the LDAPURL Bind Type
To apply an ACL when the bind DN matches the filter specified in an attribute of the targeted entry, use the LDAPURL bind type.
The userattr keyword with the LDAPURL bind type requires the following syntax:
userattr comparison_operator "attribute_name#LDAPURL"

Example 18.24. Using the LDAPURL Bind Type

To grant read and search permissions to user objects which contain the aciurl attribute set to ldap:///ou=People,dc=example,dc=com??one?(uid=user*)
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
dn: ou=People,dc=example,dc=com
changetype: modify
add: aci
aci: (targetattr = "*")
 (version 3.0; acl "Allow read,search "; allow (read,search)
 (userattr = "aciurl#LDAPURL);)
18.13.2.1.6. Matching an Attribute's Value of the Bind DN and Target DN
To apply an ACL when both the bind DN entry and the targeted entry contain an attribute set to the same value, use the following syntax:
userattr comparison_operator "attribute_name#value"

Example 18.25. Matching an Attribute's Value of the Bind DN and Target DN

To grant read and search permissions to both user performing operation and user in the tree with the l attribute set to office_1:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
dn: ou=People,dc=example,dc=com
changetype: modify
add: aci
aci: (targetattr != "userPassword")
 (version 3.0; acl "Users in the same location";
 allow (read,search) userattr = "l#office_1";)
18.13.2.1.7. Using the userattr Keyword with Inheritance
When you use the userattr keyword to associate the entry used to bind with the target entry, the ACI applies only to the target specified and not to the entries below it. In certain situations, administrators want to extend the application of the ACI several levels below the targeted entry. This is possible by using the parent keyword and specifying the number of levels below the target that should inherit the ACI.
When using the userattr keyword with the parent keyword, the syntax is as follows:
userattr comparison_operator "parent[inheritance_level].attribute_name#bind_type_or_attribute_value
  • inheritance_level: Comma-separated list that indicates how many levels below the target inherit the ACI. You can include five levels (0, 1, 2, 3, 4) below the targeted entry. Zero (0) indicates the targeted entry.
  • attribute_name: The attribute targeted by the userattr or groupattr keyword.
  • bind_type_or_attribute_value: Sets the attribute value or a bind type, such as USERDN.
For example:
userattr = "parent[0,1].manager#USERDN"
This bind rule is evaluated to be true if the bind DN matches the manager attribute of the targeted entry. The permissions granted when the bind rule is evaluated to be true apply to the target entry and to all entries immediately below it.

Example 18.26. Using the userattr Keyword with Inheritance

To enable a user to read and search the cn=Profiles,dc=example,dc=com entry where the user's DN is set in the owner attribute, as well as the first level of child entries which includes cn=mail,cn=Profiles,dc=example,dc=com and cn=news,cn=Profiles,dc=example,dc=com:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
dn: cn=Profiles,dc=example,dc=com
changetype: modify
add: aci
aci: (targetattr="*") (version 3.0; acl "Profile access",
 allow (read,search) userattr="parent[0,1].owner#USERDN" ;)

18.13.2.2. Defining Access from Specific IP Addresses or Ranges

The ip keyword in a bind rule enables you to grant or deny access from a specific IP address or a range of IP addresses.
Bind rules with the ip keyword use the following syntax:
ip comparison_operator "IP_address_or_range"

Example 18.27. Using IPv4 Address Ranges in Bind Rules

To deny access from the 192.0.2.2/24 network to the dc=example,dc=com entry:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
dn: dc=example,dc=com
changetype: modify
add: aci
aci: (targetattr = "*") (version 3.0;acl "Deny 192.0.2.2/24"; deny (all)
 (userdn = "ldap:///anyone") and (ip != "192.0.2.");)

Example 18.28. Using IPv6 Address Ranges in Bind Rules

To deny access from the 2001:db8::/64 network to the dc=example,dc=com entry:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
dn: dc=example,dc=com
changetype: modify
add: aci
aci: (targetattr = "*") (version 3.0;acl "Deny 2001:db8::/64"; deny (all)
 (userdn = "ldap:///anyone") and (ip != "2001:db8::");)

18.13.2.3. Defining Access from a Specific Host or Domain

The dns keyword in a bind rule enables you to grant or deny access from a specific host or domain.

Warning

If Directory Server cannot resolve a connecting IP address to its Fully Qualified Domain Name (FQDN) using DNS, the server does not apply ACIs with the dns bind rule for this client.
If client IP addresses are not resolvable using DNS, use the ip keyword and IP addresses instead. See Section 18.13.2.2, “Defining Access from Specific IP Addresses or Ranges”.
Bind rules with the dns keyword use the following syntax:
dns comparison_operator "host_name_or_domain_name"

Example 18.29. Defining Access from a Specific Host

To deny access from the client.example.com host to the dc=example,dc=com entry:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
dn: dc=example,dc=com
changetype: modify
add: aci
aci: (targetattr = "*") (version 3.0;acl "Deny client.example.com"; deny (all)
 (userdn = "ldap:///anyone") and (dns != "client.example.com");)

Example 18.30. Defining Access from a Specific Domain

To deny access from all hosts within the example.com domain to the dc=example,dc=com entry:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
dn: dc=example,dc=com
changetype: modify
add: aci
aci: (targetattr = "*") (version 3.0;acl "Deny example.com"; deny (all)
 (userdn = "ldap:///anyone") and (dns != "*.example.com");)

18.13.2.4. Requiring a Certain Level of Security in Connections

The security of a connection is determined by its Security Strength Factor (SSF), which sets the minimum key strength required to process operations. Using the ssf keyword in a bind rule, you can set that a connection must use a certain level of security. This enables you to force operations, for example password changes, to be performed over an encrypted connection.
The value for the SSF for any operation is the higher of the values between a TLS connection and a SASL bind. This means that if a server is configured to run over TLS and a replication agreement is configured for SASL/GSSAPI, the SSF for the operation is whichever available encryption type is more secure.
Bind rules with the ssf keyword use the following syntax:
ssf comparison_operator key_strength
You can use the following comparison operators:
  • = (equal to)
  • ! (not equal to)
  • < (less than)
  • > (greater than)
  • <= (less than or equal to)
  • >= (greater than or equal to)
If the key_strength parameter is set to 0, no secure operation is required for the LDAP operation.

Example 18.31. Requiring a Certain Level of Security in Connections

To configure that users in the dc=example,dc=com entry can only update their userPassword attribute when the SSF is 128 or higher:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
dn: dc=example,dc=com
changetype: modify
add: aci
aci: (targetattr = "userPassword") (version 3.0;
 acl "Allow users updating own userPassword";
 allow (write) (userdn = "ldap:///self") (ssf >= "128");)

18.13.2.5. Defining Access at a Specific Day of the Week

The dayofweek keyword in a bind rule enables you to grant or deny access based on the day of the week.

Note

Directory Server uses the time on the server to evaluate the ACI; not the time on the client.
Bind rules with the dayofweek keyword use the following syntax:
dayofweek comparison_operator "comma-separated_list_of_days"

Example 18.32. Granting Access on Specific Days of the Week

To deny access for the uid=user,ou=People,dc=example,dc=com user entry to bind to the server on Saturdays and Sundays:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
dn: ou=People,dc=example,dc=com
changetype: modify
add: aci
aci: (version 3.0; acl "Deny access on Saturdays and Sundays";
 deny (all)
 (userdn = "ldap:///uid=user,ou=People,dc=example,dc=com") and
 (dayofweek = "Sun,Sat");)

18.13.2.6. Defining Access at a Specific Time of Day

The timeofday keyword in a bind rule enables you to grant or deny access based on the time of day.

Note

Directory Server uses the time on the server to evaluate the ACI; not the time on the client.
Bind rules with the timeofday keyword use the following syntax:
timeofday comparison_operator "time"
You can use the following comparison operators:
  • = (equal to)
  • ! (not equal to)
  • < (less than)
  • > (greater than)
  • <= (less than or equal to)
  • >= (greater than or equal to)

Important

The timeofday keyword requires that you specify the time in 24-hour format.

Example 18.33. Defining Access at a Specific Time of a Day

To deny access for the uid=user,ou=People,dc=example,dc=com user entry to bind to the server between 6pm and 0am:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
dn: ou=People,dc=example,dc=com
changetype: modify
add: aci
 aci: (version 3.0; acl "Deny access between 6pm and 0am";
 deny (all)
 (userdn = "ldap:///uid=user,ou=People,dc=example,dc=com") and
 (timeofday >= "1800" and timeofday < "2400");)

18.13.2.7. Defining Access Based on the Authentication Method

The authmethod keyword in a bind rule sets what authentication method a client must use when connecting to the server, to apply the ACI.
Bind rules with the auth keyword use the following syntax:
authmethod comparison_operator "authentication_method"
You can set the following authentication methods:
  • none: Authentication is not required and represents anonymous access. This is the default.
  • simple: The client must provide a user name and password to bind to the directory.
  • SSL: The client must bind to the directory using a TLS certificate either in a database, smart card, or other device. For details about certificate-based authentication, see Section 9.8, “Using Certificate-based Client Authentication”.
  • SASL: The client must bind to the directory over a Simple Authentication and Security Layer (SASL) connection. When you use this authentication method in a bind rule, additionally specify the SASL mechanism, such as EXTERNAL.

Example 18.34. Enabling Access Only for Connections Using the EXTERNAL SASL Authentication Method

To deny access to the server if the connection does not use a certificate-based authentication method or SASL:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
dn: ou=People,dc=example,dc=com
changetype: modify
add: aci
aci: (version 3.0; acl "Deny all access without certificate"; deny (all)
 (authmethod = "none" or authmethod = "simple");)

18.13.2.8. Defining Access Based on Roles

The roledn keyword in a bind rule enables you to grant or deny access to users having one or multiple role set.

Note

Red Hat recommends to use groups instead of roles. For further details about roles and limitations, see Section 8.2.1, “About Roles”.
Bind rules with the roledn keyword use the following syntax:
userdn comparison_operator "ldap:///distinguished_name || ldap:///distinguished_name || ..."

Note

If a DN contains a comma, escape the comma with a backslash.

Example 18.35. Defining Access Based on Roles

To enable users that have the cn=Human Resources,ou=People,dc=example,dc=com role set in the nsRole attribute to search and read the manager attribute of entries in ou=People,dc=example,dc=com:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
dn: ou=People,dc=example,dc=com
changetype: modify
add: aci
aci: (targetattr="manager") (version 3.0;
 acl "Allow manager role to update manager attribute";
 allow (search, read) roledn = "ldap:///cn=Human Resources,ou=People,dc=example,dc=com";)

18.13.3. Combining Bind Rules Using Boolean Operators

When creating complex bind rules, the AND, OR, and NOT Boolean operators enable you to combine multiple keywords.
Bind rules combined with Boolean operators have the following syntax:
bind_rule_1 boolean_operator bind_rule_2...

Example 18.36. Combining Bind Rules Using Boolean Operators

To configure that users which are member of both the cn=Administrators,ou=Groups,dc=example,com and cn=Operators,ou=Groups,dc=example,com group can read, search, add, update, and delete entries in ou=People,dc=example,dc=com:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
dn: ou=People,dc=example,dc=com
changetype: modify
add: aci
aci: (target="ldap:///ou=People,dc=example,dc=com") (version 3.0;
 acl "Allow members of administrators and operators group to manage users";
 allow (read, search, add, write, delete)
 groupdn = "ldap:///cn=Administrators,ou=Groups,dc=example,com" AND
 groupdn = "ldap:///cn=Operators,ou=Groups,dc=example,com";)

How Directory Server Evaluates Boolean Operators

Directory Server evaluates Boolean operators by using the following rules:
  • All expressions from left to right.
    In the following example, bind_rule_1 is evaluated first:
    (bind_rule_1) OR (bind_rule_2)
  • From innermost to outermost parenthetical expressions first.
    In the following example, bind_rule_2 is evaluated first and bind_rule_3 second:
    (bind_rule_1) OR ((bind_rule_2) AND (bind_rule_3))
  • NOT before AND or OR operators.
    In the following example, bind_rule_2 is evaluated first:
    (bind_rule_1) AND NOT (bind_rule_2)
The AND and OR operators have no order of precedence.

18.14. Checking Access Rights on Entries (Get Effective Rights)

Finding the access rights that a user has on attributes within a specific entry offers a convenient way for administrators to find and control the access rights.
Get effective rights is a way to extend directory searches to display what access rights — such as read, search, write and self-write, add, and delete — a user has to a specified entry.
In Directory Server, regular users can check their rights over entries which they can view and can check other people's access to their personal entries. The Directory Manager can check rights that one user has over another user.
There are two common situations where checking the effective rights on an entry are useful:
  • An administrator can use the get effective rights command in order to better organize access control instructions for the directory. It is frequently necessary to restrict what one group of users can view or edit versus another group. For instance, members of the QA Managers group may have the right to search and read attributes like manager and salary but only HR Group members have the rights to modify or delete them. Checking the effective rights for a user or group is one way to verify that the appropriate access controls are in place.
  • A user can run the get effective rights command to see what attributes he can view or modify on his personal entry. For instance, a user should have access to attributes such as homePostalAddress and cn but may only have read access to manager and salary attributes.
There are three people involved in a get effective rights search. The first is the person running the search command, the requester. The rights are checked (with a variety of permutations) to see what rights Person A has over Entry B. The person whose rights are being checked (Person A) is the GER subject; as in, their rights are the subject of the search. The entry or entries to which the person has rights (Entry B) is the target of the search or the search base.

18.14.1. Rights Shown with a Get Effective Rights Search

Any get effective rights search, both when viewing an entry in the Directory Server Console and searching for it in the command line, shows the rights that User A has to User B's entry.
There are two kinds of access rights that can be allowed to any entry. The first are upper-level rights, rights on the entry itself, which means that kinds of operations that the User A can perform on User B's entry as a whole. The second level of access rights are more granular, show what rights for a given attribute User A has. In this case, User A may have different kinds of access permissions for different attributes in the same entry. Whatever access controls are allowed for a user are the effective rights over that entry.
For example:
entryLevelRights: vadn
attributeLevelRights: givenName:rscWO, sn:rscW, objectClass:rsc, uid:rsc, cn:rscW
Table 18.2, “Entry Rights” and Table 18.3, “Attribute Rights” show the access rights to entries and attributes, respectively, that are returned by a get effective rights search.

Table 18.2. Entry Rights

Permission Description
a Add an entry.
d Delete this entry.
n Rename the DN.
v View the entry.

Table 18.3. Attribute Rights

Permission Description
r Read.
s Search.
w Write (mod-add).
o Obliterate(mod-del). Analogous to delete.
c Compare.
W Self-write.
O Self-delete.

18.14.3. Examples of GER Searches

There are a number of different ways to run GER searches, depending on the exact type of information that needs to be returned and the types of entries and attributes being searched.

18.14.3.1. General Examples on Checking Access Rights

One common scenario for effective rights searches is for a regular user to determine what changes he can make to his personal entry.
For example, Ted Morris wants to check the rights he has to his entry. Both the -D and -E options give his entry as the requester. Since he is checking his personal entry, the -b option also contains his DN.

Example 18.37. Checking Personal Rights (User A to User A)

# ldapsearch -x -p 389 -h server.example.com -D "uid=tmorris,ou=people,dc=example,dc=com" -W -b "uid=tmorris,ou=people,dc=example,dc=com" -E '!1.3.6.1.4.1.42.2.27.9.5.2=:dn:uid=tmorris,ou=people,dc=example,dc=com' "(objectClass=*)"

 dn: uid=tmorris,ou=People,dc=example,dc=com
 givenName: Ted
 sn: Morris
 ou: IT
 ou: People
 l: Santa Clara
 manager: uid=jsmith,ou=People,dc=example,dc=com
 roomNumber: 4117
 mail: tmorris@example.com
 facsimileTelephoneNumber: +1 408 555 5409
 objectClass: top
 objectClass: person
 objectClass: organizationalPerson
 objectClass: inetOrgPerson
 uid: tmorris
 cn: Ted Morris
 userPassword: {SSHA}bz0uCmHZM5b357zwrCUCJs1IOHtMD6yqPyhxBA==
 entryLevelRights: v
 attributeLevelRights: givenName:rsc, sn:rsc, ou:rsc, l:rsc, manager:rsc, roomNumber:rscwo, mail:rscwo, facsimileTelephoneNumber:rscwo, objectClass:rsc, uid:rsc, cn:rsc, userPassword:wo
Ted Morris may, for example, be a manager or work in a department where he has to edit other user's entries, such as IT or human resources. In this case, he may want to check what rights he has to another user's entry, as in Example 18.38, “Personally Checking the Rights of One User over Another (User A to User B)”, where Ted (-D) checks his rights (-E) to Dave Miller's entry (-b):

Example 18.38. Personally Checking the Rights of One User over Another (User A to User B)

# ldapsearch -p 389 -h server.example.com -D "uid=tmorris,ou=people,dc=example,dc=com" -W -b "uid=dmiller,ou=people,dc=example,dc=com" -E '!1.3.6.1.4.1.42.2.27.9.5.2=:dn:uid=tmorris,ou=people,dc=example,dc=com' "(objectClass=*)"

dn: uid=dmiller,ou=People,dc=example,dc=com
... snip ...
entryLevelRights: vad
attributeLevelRights: givenName:rscwo, sn:rscwo, ou:rscwo, l:rscwo, manager:rsc, roomNumber:rscwo, mail:rscwo, facsimileTelephoneNumber:rscwo, objectClass:rscwo, uid:rscwo, cn:rscwo, userPassword:rswo
For all attributes, Ted Morris has read, search, compare, modify, and delete permissions to Dave Miller's entry. These results are different than the ones returned in checking Ted Morris's access to his own entry, since he personally had only read, search, and compare rights to most of these attributes.
The Directory Manager has the ability to check the rights that one user has over another user's entry. In Example 18.39, “The Directory Manager's Checking the Rights of One User over Another (User A to User B)”, the Directory Manager is checking the rights that a manager, Jane Smith (-E), has over her subordinate, Ted Morris (-b):

Example 18.39. The Directory Manager's Checking the Rights of One User over Another (User A to User B)

# ldapsearch -p 389 -h server.example.com -D "cn=Directory Manager" -W -b "uid=tmorris,ou=people,dc=example,dc=com" -E '!1.3.6.1.4.1.42.2.27.9.5.2=:dn:uid=jsmith,ou=people,dc=example,dc=com' "(objectClass=*)"

dn: uid=tmorris,ou=People,dc=example,dc=com
... snip ...
entryLevelRights: vadn
attributeLevelRights: givenName:rscwo, sn:rscwo, ou:rscwo, l:rscwo, manager:rscwo, roomNumber:rscwo, mail:rscwo, facsimileTelephoneNumber:rscwo, objectClass:rscwo, uid:rscwo, cn:rscwo, userPassword:rscwo
Only an administrator can retrieve the effective rights that a different user has on an entry. If Ted Morris tried to determine Dave Miller's rights to Dave Miller's entry, then he would receive an insufficient access error:
# ldapsearch -p 389 -h server.example.com -D "uid=dmiller,ou=people,dc=example,dc=com" -W -b "uid=tmorris,ou=people,dc=example,dc=com" -E '!1.3.6.1.4.1.42.2.27.9.5.2=:dn:uid=tmorris,ou=people,dc=example,dc=com' "(objectClass=*)"

ldap_search: Insufficient access
ldap_search: additional info: get-effective-rights: requester has no g permission on the entry
However, a regular user can run a get effective rights search to see what rights another user has to his personal entry. In Example 18.40, “Checking the Rights Someone Else Has to a Personal Entry”, Ted Morris checks what rights Dave Miller has on Ted Morris's entry.

Example 18.40. Checking the Rights Someone Else Has to a Personal Entry

# ldapsearch -p 389 -h server.example.com -D "uid=tmorris,ou=people,dc=example,dc=com" -W -b "uid=tmorris,ou=people,dc=example,dc=com" -E '!1.3.6.1.4.1.42.2.27.9.5.2=:dn:uid=dmiller,ou=people,dc=example,dc=com' "(objectClass=*)"

dn: uid=tmorris,ou=people,dc=example,dc=com
... snip ...
entryLevelRights: v
attributeLevelRights: givenName:rsc, sn:rsc, ou:rsc, l:rsc,manager:rsc, roomNumber:rsc, mail:rsc, facsimileTelephoneNumber:rsc, objectClass:rsc, uid:rsc, cn:rsc, userPassword:none
In this case, Dave Miller has the right to view the DN of the entry and to read, search, and compare the ou, givenName, l, and other attributes, and no rights to the userPassword attribute.

18.14.3.2. Examples of Get Effective Rights Searches for Non-Existent Attributes

By default, information is not given for attributes in an entry that do not have a value; for example, if the userPassword value is removed, then a future effective rights search on the entry above would not return any effective rights for userPassword, even though self-write and self-delete rights could be allowed.
Using an asterisk (*) with the get effective rights search returns every attribute available for the entry, including attributes not set on the entry.

Example 18.41. Returning Effective Rights for Non-Existent Attributes

# ldapsearch -D "cn=Directory Manager" -W -b "uid=scarter,ou=people,dc=example,dc=com" -E '!1.3.6.1.4.1.42.2.27.9.5.2=:dn:uid=scarter,ou=people,dc=example,dc=com' "(objectclass=*)" "*"  

dn: uid=scarter,ou=People,dc=example,dc=com
givenName: Sam
telephoneNumber: +1 408 555 4798
sn: Carter
ou: Accounting
ou: People
l: Sunnyvale
manager: uid=dmiller,ou=People,dc=example,dc=com
roomNumber: 4612
mail: scarter@example.com
facsimileTelephoneNumber: +1 408 555 9700
objectClass: top
objectClass: person
objectClass: organizationalPerson
objectClass: inetOrgPerson
uid: scarter
cn: Sam Carter
userPassword: {SSHA}Xd9Jt8g1UsHC8enNDrEmxj3iJPKQLItlDYdD9A==
entryLevelRights: vadn
attributeLevelRights: objectClass:rscwo, aci:rscwo, sn:rscwo, cn:rscwo, description:rscwo, seeAlso:rscwo, telephoneNumber:rscwo, userPassword:rscwo, destinationIndicator:rscwo, facsimileTelephoneNumber:rscwo, internationaliSDNNumber:rscwo, l:rscwo, ou:rscwo, physicalDeliveryOfficeName:rscwo, postOfficeBox:rscwo, postalAddress:rscwo, postalCode:rscwo, preferredDeliveryMethod:rscwo, registeredAddress:rscwo, st:rscwo, street:rscwo, teletexTerminalIdentifier:rscwo, telexNumber:rscwo, title:rscwo, x121Address:rscwo, audio:rscwo, businessCategory:rscwo, carLicense:rscwo, departmentNumber:rscwo, displayName:rscwo, employeeType:rscwo, employeeNumber:rscwo, givenName:rscwo, homePhone:rscwo, homePostalAddress:rscwo, initials:rscwo, jpegPhoto:rscwo, labeledUri:rscwo, manager:rscwo, mobile:rscwo, pager:rscwo, photo:rscwo, preferredLanguage:rscwo, mail:rscwo, o:rscwo, roomNumber:rscwo, secretary:rscwo, uid:rscwo,x500UniqueIdentifier:rscwo, userCertificate:rscwo, userSMIMECertificate:rscwo, userPKCS12:rscwo
All of the attributes available for the entry, such as secretary, are listed, even though that attribute is non-existent.

18.14.3.3. Examples of Get Effective Rights Searches for Specific Attributes or Object Classes

Taking the attribute-related GER searches further, it is possible to search for the rights to a specific attribute and set of attributes and to list all of the attributes available for one of the object classes set on the entry.
One of the options listed in the formatting example in Section 18.14.2, “The Format of a Get Effective Rights Search” is attributeList. To return the effective rights for only specific attributes, list the attributes, separated by spaces, at the end of the search command.

Example 18.42. Get Effective Rights Results for Specific Attributes

# ldapsearch -D "cn=Directory Manager" -W -b "uid=scarter,ou=people,dc=example,dc=com" -E '!1.3.6.1.4.1.42.2.27.9.5.2=:dn:uid=scarter,ou=people,dc=example,dc=com' "(objectclass=*)" cn mail initials  

dn: uid=scarter,ou=People,dc=example,dc=com
cn: Sam Carter
mail: scarter@example.com
entryLevelRights: vadn
attributeLevelRights: cn:rscwo, mail:rscwo, initials:rscwo
It is possible to specify a non-existent attribute in the attributeList, as with the initials attribute in Example 18.42, “Get Effective Rights Results for Specific Attributes”, to see the rights which are available, similar to using an asterisk to list all attributes.
The Directory Manager can also list the rights for all of the attributes available to a specific object class. This option has the format attribute@objectClass. This returns two entries; the first for the specified GER subject and the second for a template entry for the object class.

Example 18.43. Get Effective Rights Results for an Attribute within an Object Class

# ldapsearch -D "cn=Directory Manager" -W -b "uid=scarter,ou=people,dc=example,dc=com" -E '!1.3.6.1.4.1.42.2.27.9.5.2=:dn:uid=scarter,ou=people,dc=example,dc=com' "(objectclass=*)" uidNumber@posixAccount   

 ... snip ... 

dn: cn=template_posixaccount_objectclass,uid=scarter,ou=people,dc=example,dc=com
uidnumber: (template_attribute)
entryLevelRights: v
attributeLevelRights: uidNumber:rsc

Note

Using the search format attribute@objectClass is only available if the requester (-D) is the Directory Manager.
Using an asterisk (*) instead of a specific attribute returns all of the attributes (present and non-existent) for the specified GER subject and the full list of attributes for the object class template.

Example 18.44. Get Effective Rights Results for All Attributes for an Object Class

# ldapsearch -D "cn=Directory Manager" -W -b "uid=scarter,ou=people,dc=example,dc=com" -E '!1.3.6.1.4.1.42.2.27.9.5.2=:dn:uid=scarter,ou=people,dc=example,dc=com' "(objectclass=*)" *@posixaccount   

 ... snip ... 

dn: cn=template_posixaccount_objectclass,uid=scarter,ou=people,dc=example,dc=com 
objectClass: posixaccount 
objectClass: top 
homeDirectory: (template_attribute) 
gidNumber: (template_attribute) 
uidNumber: (template_attribute) 
uid: (template_attribute) 
cn: (template_attribute) 
entryLevelRights: v 
attributeLevelRights: cn:rsc, uid:rsc, uidNumber:rsc, gidNumber:rsc, homeDirectory:rsc, objectClass:rsc, userPassword:none, loginShell:rsc, gecos:rsc, description:rsc, aci:rsc

18.14.3.4. Examples of Get Effective Rights Searches for Non-Existent Entries

An administrator may want to check what rights a specific user (jsmith) would have to a non-existent user, based on the existing access control rules. For checking non-existent entries, the server generates a fake entry within that subtree. For example, to check for the fake entry cn=joe new user,cn=accounts,ou=people,dc=example,dc=com, the server creates cn=template,cn=accounts,ou=people,dc=example,dc=com.
For checking a non-existent entry, the get effective rights search can use a specified object class to generate a template entry with all of the potential attributes of the (non-existent) entry. For cn=joe new user,cn=accounts,ou=people,dc=example,dc=com with a person object class (@person), the server generates cn=template_person_objectclass,cn=accounts,ou=people,dc=example,dc=com.
When the server creates the template entry, it uses the first MUST attribute in the object class definition to create the RDN attribute (or it uses MAY if there is no MUST attribute). However, this may result in an erroneous RDN value which, in turn, violates or circumvents established ACIs for the given subtree. In that case, it is possible to specify the RDN value to use by passing it with the object class. This has the form @objectclass:rdn_attribute.
For example, to check the rights of scarter for a non-existent Posix entry with uidNumber as its RDN:
# ldapsearch -D "cn=Directory Manager" -W -b "ou=people,dc=example,dc=com" -E '!1.3.6.1.4.1.42.2.27.9.5.2=:dn:uid=scarter,ou=people,dc=example,dc=com' "(objectclass=*)" @posixaccount:uidnumber

dn: uidNumber=template_posixaccount_objectclass,ou=people,dc=example,dc=com
entryLevelRights: v
attributeLevelRights: description:rsc, gecos:rsc, loginShell:rsc, userPassword
 :rsc, objectClass:rsc, homeDirectory:rsc, gidNumber:rsc, uidNumber:rsc, uid:
 rsc, cn:rsc

18.14.3.5. Examples of Get Effective Rights Searches for Operational Attributes

Operational attributes are not returned in regular ldapsearches, including get effective rights searches. To return the information for the operational attributes, use the plus sign (+). This returns only the operational attributes that can be used in the entry.

Example 18.45. Get Effective Rights Results for Operational Attributes

# ldapsearch -D "cn=Directory Manager" -W -x -b "uid=scarter,ou=people,dc=example,dc=com" -E '!1.3.6.1.4.1.42.2.27.9.5.2=:dn:uid=scarter,ou=people,dc=example,dc=com' "(objectclass=*)" "+"  

dn: uid=scarter,ou=People,dc=example,dc=com
entryLevelRights: vadn
attributeLevelRights: nsICQStatusText:rscwo, passwordGraceUserTime:rscwo, pwdGraceUserTime:rscwo, nsYIMStatusText:rscwo, modifyTimestamp:rscwo, passwordExpWarned:rscwo, pwdExpirationWarned:rscwo, entrydn:rscwo, aci:rscwo, nsSizeLimit:rscwo, nsAccountLock:rscwo, passwordExpirationTime:rscwo, entryid:rscwo, nsSchemaCSN:rscwo, nsRole:rscwo, retryCountResetTime:rscwo, ldapSchemas:rscwo, nsAIMStatusText:rscwo, copiedFrom:rscwo, nsICQStatusGraphic:rscwo, nsUniqueId:rscwo, creatorsName:rscwo, passwordRetryCount:rscwo, dncomp:rscwo, nsTimeLimit:rscwo, passwordHistory:rscwo, pwdHistory:rscwo, nscpEntryDN:rscwo, subschemaSubentry:rscwo, nsYIMStatusGraphic:rscwo, hasSubordinates:rscwo, pwdpolicysubentry:rscwo, nsAIMStatusGraphic:rscwo, nsRoleDN:rscwo, createTimestamp:rscwo, accountUnlockTime:rscwo, copyingFrom:rscwo, nsLookThroughLimit:rscwo, nsds5ReplConflict:rscwo, modifiersName:rscwo, parentid:rscwo, passwordAllowChangeTime:rscwo, nsBackendSuffix:rscwo, nsIdleTimeout:rscwo, ldapSyntaxes:rscwo, numSubordinates:rscwo

18.14.3.6. Examples of Get Effective Rights Results and Access Control Rules

Get effective rights are returned according to whatever ACLs are in effect for the get effective rights subject entry.
For example, this ACL is set and, for the purposes of this example, it is the only ACL set:
dn: dc=example,dc=com
objectClass: top
objectClass: domain
dc: example
aci: (target=ldap:///ou=Accounting,dc=example,dc=com)(targetattr="*")(version
 3.0; acl "test acl"; allow (read,search,compare) (userdn = "ldap:///anyone") ;)

dn: ou=Accounting,dc=example,dc=com
objectClass: top
objectClass: organizationalUnit
ou: Accounting
Because the ACL does not include the dc=example,dc=com subtree, the get effective rights search shows that the user does not have any rights to the dc=example,dc=com entry:

Example 18.46. Get Effective Rights Results with No ACL Set (Directory Manager)

# ldapsearch -D "cn=Directory Manager" -W -b "dc=example,dc=com" -E '!1.3.6.1.4.1.42.2.27.9.5.2=:dn:uid=scarter,ou=people,dc=example,dc=com' "(objectclass=*)" "*@person"

dn: cn=template_person_objectclass,uid=scarter,ou=people,dc=example,dc=com
objectClass: person
objectClass: top
cn: (template_attribute)
sn: (template_attribute)
description: (template_attribute)
seeAlso: (template_attribute)
telephoneNumber: (template_attribute)
userPassword: (template_attribute)
entryLevelRights: none
attributeLevelRights: sn:none, cn:none, objectClass:none, description:none, seeAlso:none, telephoneNumber:none, userPassword:none, aci:none
If a regular user, rather than Directory Manager, tried to run the same command, the result would simply be blank.

Example 18.47. Get Effective Rights Results with No ACL Set (Regular User)

# ldapsearch -D "uid=scarter,ou=people,dc=example,dc=com" -W -b "dc=example,dc=com" -E '!1.3.6.1.4.1.42.2.27.9.5.2=:dn:uid=scarter,ou=people,dc=example,dc=com' "(objectclass=*)" "*@person"

18.14.4. Using Get Effective Rights from the Console

  1. Open the Directory tab, and right-click the entry of which to check the rights.
  2. Select Advanced Properties from the drop-down menu.
  3. Check the Show effective rights check box.
  4. Beside each attribute, the attribute-level get effective rights are displayed. The entry-level rights are shown beneath the entry's DN.
    The attribute-level effective rights (r, s, c, w, o) appear next to the attributes. The entry-level rights (v, a, d, n) appear under the full DN for the entry in the lower left-hand corner of the Property Editor.
If you check the Show all allowed attributes check box, then the effective rights for those attributes appear next to the additional attributes, even though they do not have values.

18.14.5. Get Effective Rights Return Codes

If the criticality is not set for a get effective rights search and an error occurs, the regular entry information is returned, but, in place of rights for entryLevelRights and attributeLevelRights, an error code is returned. This code can give information on the configuration of the entry that was queried. Table 18.4, “Returned Result Codes” summarizes the error codes and the potential configuration information they can relay.

Table 18.4. Returned Result Codes

Code Description
0 Successfully completed.
1 Operation error.
12 The critical extension is unavailable. If the criticality expression is set to true and effective rights do not exist on the entry being queried, then this error is returned.
16 No such attribute. If an attribute is specifically queried for access rights but that attribute does not exist in the schema, this error is returned.
17 Undefined attribute type.
21 Invalid attribute syntax.
50 Insufficient rights.
52 Unavailable.
53 Unwilling to perform.
80 Other.

18.15. Logging Access Control Information

To obtain information on access control in the error logs, you must set the appropriate log level. To set the error log level from the Console:
  1. In the Console, click the Directory tab, right-click the config node, and choose Properties from the pop-up menu.
    This displays the Property Editor for the cn=config entry.
  2. Scroll down the list of attribute value pairs to locate the nsslapd-errorlog-level attribute.
  3. Add 128 to the value already displayed in the nsslapd-errorlog-level value field.
    For example, if the value already displayed is 8192 (replication debugging), change the value to 8320. For complete information on error log levels, see the Red Hat Directory Server Configuration, Command, and File Reference.
  4. Click OK to dismiss the Property Editor.

18.16. Advanced Access Control: Using Macro ACIs

In organizations that use repeating directory tree structures, it is possible to optimize the number of ACIs used in the directory by using macros. Reducing the number of ACIs in your directory tree makes it easier to manage your access control policy and improves the efficiency of ACI memory usage.
Macros are placeholders that are used to represent a DN, or a portion of a DN, in an ACI. You can use a macro to represent a DN in the target portion of the ACI or in the bind rule portion, or both. In practice, when Directory Server gets an incoming LDAP operation, the ACI macros are matched against the resource targeted by the LDAP operation. If there is a match, the macro is replaced by the value of the DN of the targeted resource. Directory Server then evaluates the ACI normally.

18.16.1. Macro ACI Example

Figure 18.1, “Example Directory Tree for Macro ACIs” shows a directory tree which uses macro ACIs to effectively reduce the overall number of ACIs. This illustration uses repeating pattern of subdomains with the same tree structure (ou=groups, ou=people). This pattern is also repeated across the tree because the Example Corp. directory tree stores the suffixes dc=hostedCompany2,dc=example,dc=com and dc=hostedCompany3,dc=example,dc=com.
The ACIs that apply in the directory tree also have a repeating pattern. For example, the following ACI is located on the dc=hostedCompany1,dc=example,dc=com node:
aci: (targetattr="*")(targetfilter=(objectClass=nsManagedDomain))
     (version 3.0; acl "Domain access"; allow (read,search) 
     groupdn="ldap:///cn=DomainAdmins,ou=Groups,dc=hostedCompany1,dc=example,dc=com";)
This ACI grants read and search rights to the DomainAdmins group to any entry in the dc=hostedCompany1,dc=example,dc=com tree.
Example Directory Tree for Macro ACIs

Figure 18.1. Example Directory Tree for Macro ACIs

The following ACI is located on the dc=hostedCompany1,dc=example,dc=com node:
aci: (targetattr="*")(targetfilter=(objectClass=nsManagedDomain))
    (version 3.0; acl "Domain access"; allow (read,search)
    groupdn="ldap:///cn=DomainAdmins,ou=Groups,dc=hostedCompany1,dc=example,dc=com";)
The following ACI is located on the dc=subdomain1,dc=hostedCompany1,dc=example,dc=com node:
aci: (targetattr="*")(targetfilter=(objectClass=nsManagedDomain))
     (version 3.0; acl "Domain access"; allow (read,search)
     groupdn="ldap:///cn=DomainAdmins,ou=Groups,dc=subdomain1,dc=hostedCompany1,dc=example,dc=com";)
The following ACI is located on the dc=hostedCompany2,dc=example,dc=com node:
aci: (targetattr="*")(targetfilter=(objectClass=nsManagedDomain))
     (version 3.0; acl "Domain access"; allow (read,search)
     groupdn="ldap:///cn=DomainAdmins,ou=Groups,dc=hostedCompany2,dc=example,dc=com";)
The following ACI is located on the dc=subdomain1,dc=hostedCompany2,dc=example,dc=com node:
aci: (targetattr="*")(targetfilter=(objectClass=nsManagedDomain))
     (version 3.0; acl "Domain access"; allow (read,search)
     groupdn="ldap:///cn=DomainAdmins,ou=Groups,dc=subdomain1,dc=hostedCompany2,dc=example,dc=com";)
In the four ACIs shown above, the only differentiator is the DN specified in the groupdn keyword. By using a macro for the DN, it is possible to replace these ACIs by a single ACI at the root of the tree, on the dc=example,dc=com node. This ACI reads as follows:
aci: (target="ldap:///ou=Groups,($dn),dc=example,dc=com")
     (targetattr="*")(targetfilter=(objectClass=nsManagedDomain))
     (version 3.0; acl "Domain access"; allow (read,search)
     groupdn="ldap:///cn=DomainAdmins,ou=Groups,[$dn],dc=example,dc=com";)
The target keyword, which was not previously used, is utilized in the new ACI.
In this example, the number of ACIs is reduced from four to one. The real benefit is a factor of how many repeating patterns you have down and across your directory tree.

18.16.2. Macro ACI Syntax

Macro ACIs include the following types of expressions to replace a DN or part of a DN:
  • ($dn)
  • [$dn]
  • ($attr.attrName), where attrName represents an attribute contained in the target entry
In this section, the ACI keywords used to provide bind credentials, such as userdn, roledn, groupdn, and userattr, are collectively called the subject, as opposed to the target, of the ACI. Macro ACIs can be used in the target part or the subject part of an ACI.
Table 18.5, “Macros in ACI Keywords” shows in what parts of the ACI you can use DN macros:

Table 18.5. Macros in ACI Keywords

Macro ACI Keyword
($dn) target, targetfilter, userdn, roledn, groupdn, userattr
[$dn] targetfilter, userdn, roledn, groupdn, userattr
($attr.attrName) userdn, roledn, groupdn, userattr
The following restrictions apply:
  • If you use ($dn) in targetfilter, userdn, roledn, groupdn, userattr, you must define a target that contains ($dn).
  • If you use [$dn] in targetfilter, userdn, roledn, groupdn, userattr, you must define a target that contains ($dn).

Note

When using any macro, you always need a target definition that contains the ($dn) macro.
You can combine the ($dn) macro and the ($attr.attrName) macro.

18.16.2.1. Macro Matching for ($dn)

The ($dn) macro is replaced by the matching part of the resource targeted in an LDAP request. For example, you have an LDAP request targeted at the cn=all,ou=groups,dc=subdomain1,dc=hostedCompany1,dc=example,dc=com entry and an ACI that defines the target as follows:
(target="ldap:///ou=Groups,($dn),dc=example,dc=com")
The ($dn) macro matches with dc=subdomain1,dc=hostedCompany1.
When the subject of the ACI also uses ($dn), the substring that matches the target is used to expand the subject. For example:
aci: (target="ldap:///ou=*,($dn),dc=example,dc=com")
     (targetattr = "*") (version 3.0; acl "Domain access"; allow (read,search)
     groupdn="ldap:///cn=DomainAdmins,ou=Groups,($dn),dc=example,dc=com";)
In this case, if the string matching ($dn) in the target is dc=subdomain1,dc=hostedCompany1, then the same string is used in the subject. The ACI is then expanded as follows:
aci: (target="ldap:///ou=Groups,dc=subdomain1,dc=hostedCompany1,
     dc=example,dc=com") (targetattr = "*") (version 3.0; acl "Domain
     access"; allow (read,search) groupdn="ldap:///cn=DomainAdmins,ou=Groups,
     dc=subdomain1,dc=hostedCompany1,dc=example,dc=com";)
Once the macro has been expanded, Directory Server evaluates the ACI following the normal process to determine whether access is granted.

18.16.2.2. Macro Matching for [$dn]

The matching mechanism for [$dn] is slightly different than for ($dn). The DN of the targeted resource is examined several times, each time dropping the left-most RDN component, until a match is found.
For example, you have an LDAP request targeted at the cn=all,ou=groups,dc=subdomain1,dc=hostedCompany1,dc=example,dc=com subtree and the following ACI:
aci: (target="ldap:///ou=Groups,($dn),dc=example,dc=com")
     (targetattr = "*") (version 3.0; acl "Domain access"; allow (read,search)
     groupdn="ldap:///cn=DomainAdmins,ou=Groups,[$dn],dc=example,dc=com";)
The steps for expanding this ACI are as follows:
  1. ($dn) in the target matches dc=subdomain1,dc=hostedCompany1.
  2. [$dn] in the subject is replaces with dc=subdomain1,dc=hostedCompany1.
    The result is groupdn="ldap:///cn=DomainAdmins,ou=Groups,dc=subdomain1,dc=hostedCompany1,dc=example,dc=com". If the bind DN is a member of that group, the matching process stops, and the ACI is evaluated. If it does not match, the process continues.
  3. [$dn] in the subject is replaced with dc=hostedCompany1.
    The result is groupdn="ldap:///cn=DomainAdmins,ou=Groups,dc=hostedCompany1,dc=example,dc=com". In this case, if the bind DN is not a member of that group, the ACI is not evaluated. If it is a member, the ACI is evaluated.
The advantage of the [$dn] macro is that it provides a flexible way of granting access to domain-level administrators to all the subdomains in the directory tree. Therefore, it is useful for expressing a hierarchical relationship between domains.
For example, consider the following ACI:
aci: (target="ldap:///ou=*, ($dn),dc=example,dc=com")
     (targetattr="*")(targetfilter=(objectClass=nsManagedDomain))
     (version 3.0; acl "Domain access"; allow (read,search)
     groupdn="ldap:///cn=DomainAdmins,ou=Groups,[$dn],dc=example,dc=com";)
It grants access to the members of cn=DomainAdmins,ou=Groups,dc=hostedCompany1,dc=example,dc=com to all of the subdomains under dc=hostedCompany1, so an administrator belonging to that group could access a subtree like ou=people,dc=subdomain1.1,dc=subdomain1.
However, at the same time, members of cn=DomainAdmins,ou=Groups,dc=subdomain1.1 would be denied access to the ou=people,dc=hostedCompany1 and ou=people,dc=hostedCompany1 nodes.

18.16.2.3. Macro Matching for ($attr.attrName)

The ($attr.attrName) macro is always used in the subject part of a DN. For example, define the following roledn:
roledn = "ldap:///cn=DomainAdmins,($attr.ou)"
Now, assume the server receives an LDAP operation targeted at the following entry:
dn: cn=Jane Doe,ou=People,dc=HostedCompany1,dc=example,dc=com
cn: Jane Doe
sn: Doe
ou: Engineering,dc=HostedCompany1,dc=example,dc=com
...
In order to evaluate the roledn part of the ACI, the server looks at the ou attribute stored in the targeted entry and uses the value of this attribute to expand the macro. Therefore, in the example, the roledn is expanded as follows:
roledn = "ldap:///cn=DomainAdmins,ou=Engineering,dc=HostedCompany1,dc=example,dc=com"
The Directory Server then evaluates the ACI according to the normal ACI evaluation algorithm.
When an attribute is multi-valued, each value is used to expand the macro, and the first one that provides a successful match is used. For example:
dn: cn=Jane Doe,ou=People,dc=HostedCompany1,dc=example,dc=com 
cn: Jane Doe 
sn: Doe 
ou: Engineering,dc=HostedCompany1,dc=example,dc=com
ou: People,dc=HostedCompany1,dc=example,dc=com...
In this case, when the Directory Server evaluates the ACI, it performs a logical OR on the following expanded expressions:
roledn = "ldap:///cn=DomainAdmins,ou=Engineering,dc=HostedCompany1,dc=example,dc=com"

roledn = "ldap:///cn=DomainAdmins,ou=People,dc=HostedCompany1,dc=example,dc=com"

18.17. Setting Access Controls on Directory Manager

Having an unconstrained administrative user makes sense from a maintenance perspective. The Directory Manager requires a high level of access in order to perform maintenance tasks and to response to incidents.
However, because of the power of the Directory Manager user, a certain level of access control may be advisable to prevent unauthorized access or attacks from being performed as the root user.
Regular access control rules are applied to the directory tree, the Directory Manager is not a regular user entry, so no (regular) ACIs can be applied to the Directory Manager user. ACIs are applied through a special plug-in configuration entry.

18.17.1. About Access Controls on the Directory Manager Account

Normal access control rules do not apply to the Directory Manager user. The Directory Manager is defined in the dse.ldif file, not in the regular user database, and so ACI targets (Section 18.11, “Defining Targets”) which are based on an entry within a subtree do not include the Directory Manager.
Access controls for Directory Manager are implemented through the RootDN Access Control Plug-in. This plug-in applies to the Directory Server configuration, and therefore can apply some access control rules to the Directory Manager entry.
The plug-in does not define a standard ACL. Some information is already implied, including the target (the Directory Manager entry) and the allowed rights (all of them). The purpose of the RootDN Access Control Plug-in is not to restrict what the Directory Manager can do; the purpose is to provide a level of security by limiting who can log in as Directory Manager (even with valid credentials) based on their location or time.
For this reason, the ACI for the Directory Manager only sets bind rules:
As with other access control rules, deny rules supercede allow rules.

Important

Make sure that the Directory Manager always has the approproate level of access allowed. The Directory Manager may need to perform maintenance operations in off-hours (when user load is light) or to respond to failures. In that case, setting stringent time or day-based access control rules could prevent the Directory Manager from being able to adequately manage the directory.

18.17.2. Configuring the RootDN Access Control Plug-in

Root DN access control rules are disabled by default. The RootDN Access Control Plug-in must be enabled, and then the appropriate access control rules can be set.

Note

There is only one access control rule set for the Directory Manager, in the plug-in entry, and it applies to all access to the entire directory.
  1. Enable the RootDN Access Control Plug-in by setting the nsslapd-pluginEnabled attribute to on. For example:
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn: cn=RootDN Access Control Plug-in,cn=plugins,cn=config
    changetype: modify
    replace: nsslapd-pluginEnabled
    nsslapd-pluginEnabled: on
  2. Set the bind rules for the access control instruction.
    • rootdn-open-time and rootdn-close-time for time-based access controls.
    • rootdn-days-allowed for day-based access controls.
    • rootdn-allow-host, rootdn-deny-host, rootdn-allow-ip, and rootdn-deny-ip for host-based access controls. These are all multi-valued attributes.
      Deny rules supercede allow rules. For example, if rootdn-allow-host attribute is set to *.example.com, and the rootdn-deny-host attribute is set to *.front-office.example.com, anything in the front-office.example.com subdomain is prevented from logging in as Directory Manager, even though the larger example.com domain is allowed.
      Wild cards can be used to allow IP ranges or full domains.
    For example:
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn: cn=RootDN Access Control Plug-in,cn=plugins,cn=config
    changetype: modify
    add: rootdn-open-time
    rootdn-open-time: 0600
    -
    add: rootdn-close-time
    rootdn-close-time: 2100
    -
    add: rootdn-allow-host
    rootdn-allow-host: *.example.com
    -
    add: rootdn-deny-host
    rootdn-allow-host: *.remote.example.com
  3. Restart the Directory Server to load the new plug-in configuration.
    # systemctl restart dirsrv@instance

18.18. Compatibility with Previous Releases

For backward compatibility, the following deprecated ACI keywords are supported in Directory Server:
  • userdnattr
  • groupdnattr

Note

Red Hat recommends to not use these deprecated ACI keywords. These keywords will be removed from a future release of Directory Server.

Chapter 19. Managing User Authentication

When a user connects to the Red Hat Directory Server, first the user is authenticated. Then, the directory grants access rights and resource limits to the user depending upon the identity established during authentication.
This chapter describes tasks for managing users, including configuring the password and account lockout policy for the directory, denying groups of users access to the directory, and limiting system resources available to users depending upon their bind DNs.

19.1. Setting User Passwords

An entry can be used to bind to the directory only if it has a userPassword attribute and if it has not been inactivated. Because user passwords are stored in the directory, the user passwords can be set or reset with any LDAP operation, like ldapmodify.
For information on creating and modifying directory entries, see Chapter 3, Managing Directory Entries. For information on inactivating user accounts, see Section 19.15, “Manually Inactivating Users and Roles”.
Passwords can also be set and reset in the Users and Groups area of the Red Hat Administration Server or Directory Server Console. For information on how to use the Users and Groups area in the Administration Server Console, see the online help that is available in the Red Hat Administration Server.
Only password administrators, described in Section 19.2, “Setting Password Administrators”, and the root DN can add pre-hashed passwords. These users can also violate password policy.

Warning

When using a password administrator account or the Directory Manager (root DN) to set a password, password policies are bypassed and not verified. Do not use these accounts for regular user password management. Use them only to perform password administration tasks that require bypassing the password policies.

19.2. Setting Password Administrators

The Directory Manager can add the password administrator role to a user or a group of users. Since access control instructions (ACI) need to be set, it is recommended that a group is used to allow just a single ACI set to manage all password administrators. A password administrator can perform any user password operations, including the following:
  • forcing the user to change their password,
  • changing a user's password to a different storage scheme defined in the password policy,
  • bypassing the password syntax checks,
  • and adding already hashed passwords.
As explained in Section 19.1, “Setting User Passwords”, it is recommended that ordinary password updates are done by an existing role in the database with permissions to update only the userPassword attribute. We recommend not to use the password administrator account for these ordinary tasks.
To specify a user or a group of users as password administrator in a local policy, use ldapmodify to set the passwordAdminDN attribute in the main configuration entry.
# ldapmodify -h localhost -p 389 -D "cn=Directory Manager" -W
dn: cn=cn\3DnsPwPolicyEntry\2Cou\3DPeople\2Cdc\3Dexample\2Cdc\3Dcom,cn=nsPwPolicyContainer,ou=People,dc=example,dc=com
changetype: modify
replace: passwordAdminDN
passwordAdminDN: cn=Passwd Admins,ou=groups,dc=example,dc=com
For setting in the global policy:
# ldapmodify  -h localhost -p 389 -D "cn=Directory Manager" -W
dn: cn=config
changetype: modify
replace: passwordAdminDN
passwordAdminDN: cn=Passwd Admins,ou=groups,dc=example,dc=com

19.3. Changing Passwords Stored Externally

While most passwords can be changed through the Console and other Directory Server features or through the ldapmodify operation, there are some passwords that cannot be changed through regular LDAP operations. These passwords may be stored outside the Directory Server, such as passwords stored in a SASL application. These passwords can be modified through the password change extended operation.
Directory Server supports the password change extended operation as defined in RFC 3062, so users can change their passwords, using a suitable client, in a standards-compliant way. The ldappasswd utility passes the changes for the password for the specified user:
# ldappasswd -x -D bind_dn -W -p server_port -h server_hostname [-a oldPassword] [-s newPassword] [user]

Important

Password operations must be performed over a secure connection, meaning SASL, TLS, or Start TLS. For information on using secure connections with LDAP client tools, see Section 9.8.4, “Authenticating Using a Certificate”.

Table 19.1. ldappasswd Options

Parameter Description
-h Gives the host name of the Directory Server.
-p Gives the port number of the Directory Server. Since TLS is required for password change operations, this is usually give the TLS port of the Directory Server. With the -ZZ or -ZZZ for Start TLS, this can be the standard port.
-D Gives the bind DN.
-w Gives the password for the bind DN.
-x Disables SASL to allow a simple bind over an TLS connection.
-a Optional. Gives the old password, which is being changed.
-s Optional. Sets the new password.
user Optional. Gives the DN of the user entry for which to change the password.
To use Start TLS, which runs the command on a non-secure port, run ldappasswd with the -ZZ option and the standard LDAP port number. The password extended change operation has the following format:
# ldappasswd -x -D bind_dn -W -p server_port -h server_hostname -Z [-a oldPassword] [-s newPassword] [user]

Note

For Start TLS connections to work, the TLS environment variables must be configured as described in Section 9.8.4, “Authenticating Using a Certificate”.
Use the -ZZ option to force the connection to be successful.
To modify an entry's password, run ldappasswd like any other LDAP operation. It is not necessary to specify a user if the account is the same as that given in the bind DN. For example:
# ldappasswd -x -h ldap.example.com -p 389 -ZZ -D "uid=jsmith,ou=People,dc=example,dc=com" -W -s newpassword
To change the password on an entry other than the one specified in the bind credentials, run ldappasswd as shown below, adding the user DN to the operation and providing separate credentials, as follows:
# ldappasswd -D "cn=Directory Manager" -W -p 389 -h server.example.com -x -ZZ -s newpassword "uid=jsmith,ou=People,dc=example,dc=com"
Access control is enforced for the password change operation. If the bind DN does not have rights to change the specified password, the operation will fail with an Insufficient rights error.

19.4. Managing the Password Policy

A password policy minimizes the risks of using passwords by enforcing a certain level of security. For example, a password policy can define that:
  • Users must change their passwords according to a schedule.
  • Users must provide non-trivial passwords.
  • The password syntax must meet certain complexity requirements.
For an overview on password policy, see "Designing a Password Policy" in the "Designing a Secure Directory" chapter in the Deployment Guide.

Warning

When using a password administrator account or the Directory Manager (root DN) to set a password, password policies are bypassed and not verified. Do not use these accounts for regular user password management. Use them only to perform password administration tasks that require bypassing the password policies.
Directory Server supports fine-grained password policy, so password policies can be applied to the entire directory (global password policy), a particular subtree (subtree-level or local password policy), or a particular user (user-level or local password policy).
The complete password policy applied to a user account is comprised of the following elements:
  • The type or level of password policy checks. This information indicates whether the server should check for and enforce a global password policy or local (subtree/user-level) password policies.
    Password policies work in an inverted pyramid, from general to specific. A global password policy is superseded by a subtree-level password policy, which is superseded by a user-level password policy. Only one password policy is enforced for the entry; password policies are not additive. This means that if a particular attribute is configured in the global or subtree-level policy, but not in the user-level password policy, the attribute is not used for the user when a login is attempted because the active, applied policy is the user-level policy.
  • Password add and modify information. The password information includes password syntax and password history details.
  • Bind information. The bind information includes the number of grace logins permitted, password aging attributes, and tracking bind failures.

Note

After establishing a password policy, user passwords can be protected from potential threats by configuring an account lockout policy. Account lockout protects against hackers who try to break into the directory by repeatedly guessing a user's password.

19.4.1. Configuring the Global Password Policy

Note

After configuring the password policy, configure an account lockout policy. For details, see Section 19.8, “Configuring a Password-Based Account Lockout Policy”.

19.4.1.1. Configuring a Global Password Policy Using the Console

A global password policy applies to every entry in the entire directory.
  1. Select the Configuration tab and then the Data node.
  2. In the right pane, select the Passwords tab.
    This tab contains the password policy for the entire Directory Server.
  3. Set the password policies for how users can change their own passwords.
    • To require users to change their password the first time they log on, select the User must change password after reset check box.
    • To allow users to change their own passwords, select the User may change password check box.
    • To prevent users from changing their password for a specific duration, enter the number of days in the Allow changes in X day(s) text box. This keeps users from quickly cycling through passwords to reuse a password in their password history.
    • For the server to maintain a history list of passwords used by each user, select the Keep password history check box. Enter the number of passwords for the server to keep for each user in the Remember X passwords text box.
  4. Set the policies for when passwords expire.
    • If user passwords should not expire, select the Password never expires radio button.
    • To require users to change their passwords periodically, select the Password expires after X days radio button, and then enter the number of days that a user password is valid.
      The maximum value for the password age is derived by subtracting January 18, 2038, from today's date. The entered value must not be set to the maximum value or too close to the maximum value. Setting the value to the maximum value can cause the Directory Server to fail to start because the number of seconds will go past the epoch date. In such an event, the error log will indicate that the password maximum age is invalid. To resolve this problem, correct the passwordMaxAge attribute value in the dse.ldif file.
      A common policy is to have passwords expire every 30 to 90 days. By default, the password maximum age is set to 8640000 seconds (100 days).
    • If the Password expire after X days radio button is selected, specify how long before the password expires to send a warning to the user. In the Send Warning X Days Before Password Expires text enter the number of days before password expiration to send a warning.

      Note

      It is not necessary to configure the Directory Server to send a warning to users. The Directory Server automatically issues a warning the next time the user attempts to log into the Directory Server Console that the password will soon expire or has expired. This is analogous to an operating system warning that reads "Warning: password will expire in 7 days" when a user logs in.
  5. For the server to check the syntax of a user password to make sure it meets the minimum requirements set by the password policy, select the Check Password Syntax check box. Then, specify required password complexity, such as the minimum length and required number of numeric and special characters.
  6. From the Password Encryption pull-down menu, select the encryption method for the server to use when storing passwords.
    For a list of supported password storage schemes, see the corresponding section in the Red Hat Directory Server Configuration, Command, and File Reference.
  7. Click Save.

19.4.1.2. Configuring a Global Password Policy Using the Command Line

To set up the password policy for a subtree or user, add the required entries and attributes at the subtree- or user-level, set the appropriate values to the password policy attributes, and enable fine-grained password policy checking.
No password policy attributes are set by default. Each password policy attribute must be added manually to the cn=config entry to create a global policy. These can be passed all together by passing an LDIF file with ldapmodify.
  1. Create the LDIF file. Each statement is the same as inputting the changes through stdin, with separate update statements separated by a dash (-).
    dn: cn=config
    changetype: modify
    add: passwordChange
    passwordChange: on
    -
    add: passwordExp
    passwordExp: on
    -
    add: passwordMaxAge
    passwordMaxAge: 8640000
    -
    add: passwordCheckSyntax
    passwordCheckSyntax: on
    -
    add: passwordMinCategories
    passwordMinCategories: 3
    -
    add: passwordStorageScheme
    passwordStorageScheme: SSHA512
    ^D
    The following table displays the attributes you can use to configure the password policy:

    Table 19.2. Password Policy-related Attributes

    passwordChange passwordCheckSyntax passwordExp
    passwordGraceLimit passwordHistory passwordInHistory
    passwordMaxAge passwordMaxRepeats passwordMin8bit
    passwordMinAge passwordMinAlphas passwordMinCategories
    passwordMinDigits passwordMinLength passwordMinLowers
    passwordMinSpecials passwordMinTokenLength passwordMinUppers
    passwordMustChange passwordSendExpiringTime passwordStorageScheme
    passwordTrackUpdateTime passwordWarning
    For further details about the parameters, see the Red Hat Directory Server Configuration, Command, and File Reference.
  2. Pass the LDIF file to the server using the -f option with the ldapmodify command.
    # ldapmodify -D "cn=Directory Manager" -W -x -f user-pwdpolicy.ldif

19.4.2. Configuring a Local Password Policy

Note

After configuring the password policy, configure an account lockout policy. For details, see Section 19.8, “Configuring a Password-Based Account Lockout Policy”.

19.4.2.1. Configuring a Subtree/User Password Policy Using the Console

  1. Enable a fine-grained password policy globally, as described in Section 19.4.1.1, “Configuring a Global Password Policy Using the Console”. Be sure to check the Enable fine-grained password policy check box to allow user-level password policies.

    Note

    The global password policy does not override the local policy if they differ.
  2. Create the local password policy for the subtree or user.
    1. Select the Directory tab.
    2. In the navigation pane, select the subtree or user entry for which to set up the password policy.
    3. From the Object menu, select the Manage Password Policy option, and then select the For user or For subtree.
    4. In the Passwords tab, select the Create subtree/user level password policy check box to add the required attributes. The password policy settings — resetting, expiration, syntax, and encryption — are the same as for the global policy in Section 19.4.1.1, “Configuring a Global Password Policy Using the Console”.
    5. In the Account Lockout tab, specify the appropriate information, and click Save.

19.4.2.2. Configuring Subtree/User Password Policy Using the Command Line

  1. Add the required attributes to the subtree or user entries by running the ns-newpwpolicy.pl script.
    The command syntax for the script is as follows:
    # ns-newpwpolicy.pl [-D rootDN]  -w password | -w - | -j filename [-p port] [-h host] -U userDN -S suffixDN
    For updating a subtree entry, use the -S option. For updating a user entry, use the -U option. The ns-newpwpolicy.pl script accepts only one user or subtree entry at a time. It can, however, accept both user and suffix entries at the same time. For details about the script, see the Red Hat Directory Server Configuration, Command, and File Reference.
  2. The script adds the required attributes depending on whether the target entry is a subtree or user entry.
    For a subtree (for example, ou=people,dc=example,dc=com), the following entries are added:
    • A container entry (nsPwPolicyContainer) at the subtree level for holding various password policy-related entries for the subtree and all its children. For example:
      dn: cn=nsPwPolicyContainer,ou=people,dc=example,dc=com
      objectClass: top
      objectClass: nsContainer
      cn: nsPwPolicyContainer
    • The actual password policy specification entry (nsPwPolicyEntry) for holding all the password policy attributes that are specific to the subtree. For example:
      dn: cn="cn=nsPwPolicyEntry,ou=people,dc=example,dc=com",
           cn=nsPwPolicyContainer,ou=people,dc=example,dc=com
      objectclass: top
      objectclass: extensibleObject
      objectclass: ldapsubentry
      objectclass: passwordpolicy
    • The CoS template entry (nsPwTemplateEntry) that has the pwdpolicysubentry value pointing to the above (nsPwPolicyEntry) entry. For example:
      dn: cn="cn=nsPwTemplateEntry,ou=people,dc=example,dc=com",
           cn=nsPwPolicyContainer,ou=people,dc=example,dc=com
      objectclass: top
      objectclass: extensibleObject
      objectclass: costemplate
      objectclass: ldapsubentry
      cosPriority: 1
      pwdpolicysubentry: cn="cn=nsPwPolicyEntry,ou=people,dc=example,dc=com",
           cn=nsPwPolicyContainer,ou=people,dc=example,dc=com
    • The CoS specification entry at the subtree level. For example:
      dn: cn=newpwdpolicy_cos,ou=people,dc=example,dc=com
      objectclass: top
      objectclass: LDAPsubentry
      objectclass: cosSuperDefinition
      objectclass: cosPointerDefinition
      cosTemplateDn: cn=cn=nsPwTemplateEntry\,ou=people\,dc=example,dc=com,
           cn=nsPwPolicyContainer,ou=people,dc=example,dc=com
      cosAttribute: pwdpolicysubentry default operational
    For a user (for example, uid=jdoe,ou=people,dc=example,dc=com), the following entries are added:
    • A container entry (nsPwPolicyContainer) at the parent level for holding various password policy related entries for the user and all its children. For example:
      dn: cn=nsPwPolicyContainer,ou=people,dc=example,dc=com
      objectClass: top
      objectClass: nsContainer
      cn: nsPwPolicyContainer
    • The actual password policy specification entry (nsPwPolicyEntry) for holding the password policy attributes that are specific to the user. For example:
      dn: cn="cn=nsPwPolicyEntry,uid=jdoe,ou=people,dc=example,dc=com",
           cn=nsPwPolicyContainer,ou=people,dc=example,dc=com
      objectclass: top
      objectclass: extensibleObject
      objectclass: ldapsubentry
      objectclass: passwordpolicy
  3. Assign the value of the above entry DN to the pwdpolicysubentry attribute of the target entry. For example, this assigns the password policy to the user entry:
    dn: uid=jdoe,ou=people,dc=example,dc=com
    changetype: modify
    replace: pwdpolicysubentry
    pwdpolicysubentry: cn="cn=nsPwPolicyEntry,uid=jdoe,ou=people,dc=example,dc=com",
         cn=nsPwPolicyContainer,ou=people,dc=example,dc=com
  4. Set the password policy attributes for the subtree or user entry with the appropriate values.
    Table 19.2, “Password Policy-related Attributes” lists the attributes available to configure the password policy. The ldapmodify utility can be used to change these attributes in the subtree or user entry which contains the nsPwPolicyEntry object class.

    Note

    The nsslapd-pwpolicy-local attribute of the cn=config entry controls the type of password policy the server enforces. By default, this attribute is disabled (off). When the attribute is disabled, the server only checks for and enforces the global password policy; the subtree and user-level password policies are ignored. When the ns-newpwpolicy.pl script runs, it first checks for the specified subtree and user entries and, if they exist, modifies them. After updating the entries successfully, the script sets the nsslapd-pwpolicy-local configuration parameter to on. If the subtree and user-level password policy should not be enabled, be sure to set nsslapd-pwpolicy-local to off after running the script.
To turn off user- and subtree-level password policy checks, set the nsslapd-pwpolicy-local attribute to off by modifying the cn=config entry. For example:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: cn=config
changetype: modify
replace: nsslapd-pwpolicy-local
nsslapd-pwpolicy-local: off
This attribute can also be disabled by modifying it directly in the configuration file (dse.ldif).
  1. Stop the server.
    # systemctl stop dirsrv.target instance
  2. Open the dse.ldif file in a text editor.
  3. Set the value of nsslapd-pwpolicy-local to off, and save.
    nsslapd-pwpolicy-local: off
  4. Start the server.
    sy# stemctl start dirsrv.target instance

19.5. Understanding Password Expiration Controls

When a user authenticates to Directory Server using a valid password, and if the password is expired, will expire soon, or needs to be reset, the server sends the following LDAP controls back to the client:
  • Expired control (2.16.840.1.113730.3.4.4): Indicates that the password is expired. Directory Server sends this control in the following situations:
    • The password is expired, and grace logins have been exhausted. The server rejects the bind with an Error 49 message.
    • The password is expired, but grace logins are still available. The bind will be allowed.
    • If passwordMustChange is enabled in the cn=config entry, and a user needs to reset the password after an administrator changed it. The bind is allowed, but any subsequent operation, other than changing the password, results in an Error 53 message.
  • Expiring control (2.16.840.1.113730.3.4.5): Indicates that the password will expire soon. Directory Server sends this control in the following situations:
    • The password will expire within the password warning period set in the passwordWarning attribute in the cn=config entry.
    • If the password policy configuration option is enabled in the passwordSendExpiringTime attribute in the cn=config entry, the expiring control is always returned, regardless of whether the password is within the warning period.
  • Bind response control (1.3.6.1.4.1.42.2.27.8.5.1): The control contains detailed information about the state of the password that is about to expire or will expire soon.

    Note

    Directory Server only sends the bind response control if the client requested it. For example, if you use ldapsearch, you must pass the -e ppolicy parameter to the command to request the bind response control.

    Example 19.1. Requesting the Bind Response Control in a Query

    If you request the bind response control, for example by passing the -e ppolicy parameter to the ldapsearch command, the server returns detailed information about account expiration. For example:
    # ldapsearch -D "uid=user_name,dc=example,dc=com" -xLLL -W \
         -b "dc=example,dc=com" -e ppolicy
    ldap_bind: Success (0); Password expired (Password expired, 1 grace logins remain)

19.6. Managing the Directory Manager Password

The Directory Manager is the privileged database administrator, comparable to the root user in Linux. The Directory Manager entry and the corresponding password are set during the instance installation.
The default distinguished name (DN) of the Directory Manager is cn=Directory Manager.

Warning

Do not use curly braces ({}) in the password. Directory Server stores the password in the {password-storage-scheme}hashed_password format. The server interprets characters in curly braces as the password storage scheme. If the string is an invalid storage scheme or if the password is not correctly hashed, the Directory Manager cannot connect to the server.

19.6.1. Resetting the Directory Manager Password

If you lose the Directory Manager password, reset it:
  1. Stop the Directory Server instance:
    # systemctl stop dirsrv@instance_name
  2. Generate a new password hash. For example:
    # pwdhash -D /etc/dirsrv/slapd-instance_name password
    {SSHA512}2eyW2uSFhh8LeB/nwZipfvFhSwL2DKZ58kXrCXsxr98Vz0nZI8fhd0W5BbL321Sr9Ulhzo3LhiQLiv4iVGF7hEGezIka65kN
    Specifying the path to the Directory Server configuration automatically uses the password storage scheme set in the nsslapd-rootpwstoragescheme attribute to encrypt the new password.
  3. Edit the /etc/dirsrv/slapd-instance_name/dse.ldif file and set the nsslapd-rootpw attribute to the value displayed in the previous step:
    nsslapd-rootpw: {SSHA512}2eyW2uSFhh8LeB/nwZipfvFhSwL2DKZ58kXrCXsxr98Vz0nZI8fhd0W5BbL321Sr9Ulhzo3LhiQLiv4iVGF7hEGezIka65kN
  4. Start the Directory Server instance:
    # systemctl start dirsrv@instance_name

19.6.2. Changing the Directory Manager Password

19.6.2.1. Changing the Directory Manager Password Using the Command Line

To change the Directory Manager password using the command line, your server must support encrypted connections. If your server does not support encrypted connections, use the Directory Server Console to update the Directory Manager password. See Section 19.6.2.2, “Changing the Directory Manager Password Using the Directory Server Console”.
If your server supports encrypted connections, perform these steps to change the password:
  1. Generate a new password hash. For example:
    # pwdhash -D /etc/dirsrv/slapd-instance_name password
    {SSHA512}2eyW2uSFhh8LeB/nwZipfvFhSwL2DKZ58kXrCXsxr98Vz0nZI8fhd0W5BbL321Sr9Ulhzo3LhiQLiv4iVGF7hEGezIka65kN
    Specifying the path to the Directory Server configuration automatically uses the password storage scheme set in the nsslapd-rootpwstoragescheme attribute to encrypt the new password.
  2. Set the nsslapd-rootpw attribute to the value displayed in the previous step using a secure connection (STARTTLS):
    # ldapmodify -W -x -D "cn=Directory Manager" -p 389 -h server.example.com -x -ZZ
    
    dn: cn=config
    changetype: modify
    replace: nsslapd-rootpw
    nsslapd-rootpw: {SSHA512}2eyW2uSFhh8LeB/nwZipfvFhSwL2DKZ58kXrCXsxr98Vz0nZI8fhd0W5BbL321Sr9Ulhzo3LhiQLiv4iVGF7hEGezIka65kN

19.6.2.2. Changing the Directory Manager Password Using the Directory Server Console

As the administrator, perform these steps to change the password:
  1. Open the Directory Server Console. For details, see Section 1.3.1, “Opening the Directory Server Console”.
  2. In the Configuration tab, select the host name in the left pane and click the Manager tab.
  3. Enter a new password and confirm it.
  4. Click Save.

19.6.3. Changing the Directory Manager Password Storage Scheme

The password storage scheme specifies which algorithm Directory Server uses to hash a password. To change the storage scheme using the command line, your server must support encrypted connections. If your server does not support encrypted connections, use the Directory Server Console to set the storage scheme. See Section 19.6.3.2, “Changing the Directory Manager Password Storage Scheme Using the Console”.
Note that the storage scheme of the Directory Manager (nsslapd-rootpwstoragescheme) can be differ than the scheme used to encrypt user passwords (nsslapd-pwstoragescheme).
For a list of supported password storage schemes, see the corresponding section in the Red Hat Directory Server Configuration, Command, and File Reference.

Note

If you change the Directory Manager's password storage scheme you must also reset its password. Existing passwords cannot be re-encrypted.

19.6.3.1. Changing the Directory Manager Password Storage Scheme Using the Command Line

If your server supports encrypted connections, perform these steps to change the password storage scheme:
  1. Generate a new password hash that uses the new storage scheme. For example:
    # pwdhash -s SSHA512 password
    {SSHA512}2eyW2uSFhh8LeB/nwZipfvFhSwL2DKZ58kXrCXsxr98Vz0nZI8fhd0W5BbL321Sr9Ulhzo3LhiQLiv4iVGF7hEGezIka65kN
  2. Set the nsslapd-rootpwstoragescheme attribute to the storage scheme and the nsslapd-rootpw attribute to the value displayed in the previous step using a secure connection (STARTTLS):
    # ldapmodify -W -x -D "cn=Directory Manager" -p 389 -h server.example.com -x -F
    
    dn: cn=config
    changetype: modify
    replace: nsslapd-rootpwstoragescheme
    nsslapd-rootpwstoragescheme: SSHA512
    -
    replace: nsslapd-rootpw
    nsslapd-rootpw: {SSHA512}2eyW2uSFhh8LeB/nwZipfvFhSwL2DKZ58kXrCXsxr98Vz0nZI8fhd0W5BbL321Sr9Ulhzo3LhiQLiv4iVGF7hEGezIka65kN

19.6.3.2. Changing the Directory Manager Password Storage Scheme Using the Console

As the administrator, perform these steps to change the Directory Manager password storage scheme:
  1. Open the Directory Server Console. For details, see Section 1.3.1, “Opening the Directory Server Console”.
  2. In the Configuration tab, select to the host name in the left pane and click the Manager tab.
  3. Select a new password storage scheme in the Manager password encryption field.
  4. Enter a new password and confirm it.
  5. Click Save.

19.6.4. Changing the Directory Manager DN

19.6.4.1. Changing the Directory Manager DN Using the Command Line

As the administrator, perform the following step to change the Directory Manager DN to cn=New Directory Manager:
# ldapmodify -W -x -D "cn=Directory Manager" -p 389 -h server.example.com -x

dn: cn=config
changetype: modify
replace: nsslapd-rootdn
nsslapd-rootdn: cn=New Directory Manager

19.6.4.2. Changing the Directory Manager DN Using the Console

As the administrator, perform these steps to change the Directory Manager DN:
  1. Open the Directory Server Console. For details, see Section 1.3.1, “Opening the Directory Server Console”.
  2. In the Configuration tab, select to the host name in the left pane and click the Manager tab.
  3. Enter a new DN for the Directory Manager into the Directory Manager DN field.
  4. Click Save.

19.7. Checking Account Availability for Passwordless Access

Most of the time, for the Directory Server to return authentication information about a user account, a client actually binds (or attempts to bind) as that user. And a bind attempt requires some sort of user credentials, usually a password or a certificate. While the Directory Server allows unauthenticated binds and anonymous binds, neither of those binds returns any user account information.
There are some situations where a client requires information about a user account — specifically whether an account should be allowed to authenticate — in order to perform some other operation, but the client either does not have or does use any credentials for the user account in Directory Server. Essentially, the client needs to perform a credential-less yet authenticated bind operation to retrieve the user account information (including password expiration information, if the account has a password).
This can be done through an ldapsearch by passing the Account Usability Extension Control. This control acts as if it performs an authenticated bind operation for a given user and returns the account status for that user — but without actually binding to the server. This allows a client to determine whether that account can be used to log in and then to pass that account information to another application, like PAM.
For example, using the Account Usability Extension Control can allow a system to use the Directory Server as its identity back end to store user data but to employ password-less authentication methods, like smart cards or SSH keys, where the authentication operation is performed outside Directory Server.

19.7.2. Changing What Users Can Perform an Account Usability Search

By default, only the Directory Manager can use the Account Usability Extension Control. Other users can use the Account Usability Extension Control by setting the appropriate ACI on the supported control entry. The control entry is named for the Account Usability Extension Control OID, 1.3.6.1.4.1.42.2.27.9.5.8.
For example, to enable members of the cn=Administrators,ou=groups,dc=example,dc=com group to read the Account Usability Extension Control of all users:
# ldapmodify -D "cn=Directory Manager" -W -x

dn: oid=1.3.6.1.4.1.42.2.27.9.5.8,cn=features,cn=config
changetype: modify
add: aci
aci: (targetattr = "*")(version 3.0; acl "Account Usable"; allow (read)(groupdn = "ldap:///cn=Administrators,ou=groups,dc=example,dc=com");)

19.8. Configuring a Password-Based Account Lockout Policy

A password-based account lockout policy protects against hackers who try to break into the directory by repeatedly trying to guess a user's password. The password policy can be set so that a specific user is locked out of the directory after a given number of failed attempts to bind.

19.8.1. Configuring the Account Lockout Policy Using the Console

To set up or modify the account lockout policy for the Directory Server:
  1. Select the Configuration tab and then the Data node.
  2. In the right pane, select the Account Lockout tab.
  3. To enable account lockout, select the Accounts may be locked out check box.
  4. Enter the maximum number of allowed bind failures in the Lockout account after X login failures text box. The server locks out users who exceed the limit specified here.
  5. In the Reset failure counter after X minutes text box, enter the number of minutes for the server to wait before resetting the bind failure counter to zero.
  6. Set the interval for users to be locked out of the directory.
    • Select the Lockout Forever radio button to lock users out until their passwords have been reset by the administrator.
    • Set a specific lockout period by selecting the Lockout Duration radio button and entering the time (in minutes) in the text box.
  7. Click Save.

19.8.2. Configuring the Account Lockout Policy Using the Command Line

Use ldapmodify to configure account lockout policy settings in the cn=config entry. For example:
# ldapmodify -D "cn=Directory Manager" -W -x -p 389 -h server.example.com -x
dn: cn=config
changetype: modify
replace: passwordLockout
passwordLockout: on
-
add: passwordMaxFailure
passwordMaxFailure: 4
-
add: passwordLockoutDuration
passwordLockoutDuration: 600
-
Attributes related to account lockout policy are described in the Red Hat Directory Server Configuration, Command, and File Reference.
The following attributes control the account password policy:

19.8.3. Disabling Legacy Password Lockout Behavior

There are different ways of interpreting when the maximum password failure (passwordMaxFailure) has been reached. It depends on how the server counts the last failed attempt in the overall failure count.
The traditional behavior for LDAP clients is to assume that the failure occurs after the limit has been reached. So, if the failure limit is set to three, then the lockout happens at the fourth failed attempt. This also means that if the fourth attempt is successful, then the user can authenticate successfully, even though the user technically hit the failure limit. This is n+1 on the count.
LDAP clients increasingly expect the maximum failure limit to look at the last failed attempt in the count as the final attempt. So, if the failure limit is set to three, then at the third failure, the account is locked. A fourth attempt, even with the correct credentials, fails. This is n on the count.
The first scenario — where an account is locked only if the attempt count is exceeded — is the historical behavior, so this is considered a legacy password policy behavior. In Directory Server, this policy is enabled by default, so an account is only locked when the failure count is n+1. This legacy behavior can be disabled so that newer LDAP clients receive the error (LDAP_CONSTRAINT_VIOLATION) when they expect it. This is set in the passwordLegacyPolicy parameter.
For example:
[root@server ~]# ldapmodify -D "cn=Directory Manager" -x -D "cn=directory manager" -W -p 389 -h server.example.com -x
dn: cn=config
replace: passwordLegacyPolicy
passwordLegacyPolicy: off

19.9. Configuring Time-Based Account Lockout Policies

Aside from locking accounts for failed authentication attempts, another method of defining an account lockout policy is to base it on account inactivity or an account age. The Account Policy Plug-in uses a relative time setting to determine whether an account should be locked.

Note

Roles or classes of service can be used to inactivate accounts based on absolute account times. For example, a CoS can be created that inactivates every account created before a certain date.
The Account Policy Plug-in requires three configuration entries:
  • A configuration entry for the plug-in itself. This sets global values that are used for all account policies configured on that server.
  • An account policy configuration entry. This entry is within the user directory and is essentially a template which is referenced and applied to user account entries.
  • An entry which applies the account policy entry. A user account can reference an account policy directly or a CoS or role can be used to apply account policies to sets of user accounts automatically.

    Note

    An account policy is applied through the acctPolicySubentry attribute. While this attribute can be added directly to user accounts, this attribute is single-valued — which means that only one account policy can be applied to that account.
    That may be fine in most cases. However, an organization could realistically create two account policies, one for account inactivity and then another for account expiration based on age.
    Using a CoS to apply account policies allows multiple account policies to be used for an account.

19.9.1. Account Policy Plug-in Syntax

The Account Policy Plug-in itself only has two configuration attributes:
  • nsslapd-pluginEnabled, which sets whether the plug-in is enabled or disabled. This attribute is off by default.
  • nsslapd-pluginarg0, which points to he DN of the plug-in configuration directory. The configuration entry is usually a child entry of the plug-in itself, such as cn=config,cn=Account Policy Plugin,cn=plugins,cn=config.
Past that, account policies are defined in two parts:
  • The plug-in configuration entry identified in the nsslapd-pluginarg0 attribute. This sets global configuration for the plug-in to use to identify account policy configuration entries and to manage user account entries. These settings apply across the server.
    The configuration entry attributes are described in the Account Policy Plug-in Attributes section in the Red Hat Directory Server Configuration, Command, and File Reference.
  • The account policy configuration entry. This is much like a template entry, which sets specific values for the account policies. User accounts — either directly or through CoS entries — reference this account policy entry.
    The account policy and user entry attributes are described in the following table:

    Table 19.4. Account Policy Entry and User Entry Attributes

    Attribute Definition Configuration or User Entry
    accountpolicy (object class) Defines a template entry for account inactivation or expiration policies. Configuration
    accountInactivityLimit (attribute) Sets the time period, in seconds, from the last login time of an account before that account is locked for inactivity. Configuration
    acctPolicySubentry (attribute) Identifies any entry which belongs to an account policy (specifically, an account lockout policy). The value of this attribute points to the DN of the account policy which is applied to the entry. User
    createTimestamp (operational attribute) Contains the date and time that the entry was initially created. User
    lastLoginTime (operational attribute) Contains a timestamp of the last time that the given account authenticated to the directory. User
    For further details, see the attribute's description in the Red Hat Directory Server Configuration, Command, and File Reference

19.9.2. Account Inactivity and Account Expiration

The Account Policy plug-in enables you to set up:
  • account expiration: Accounts are disabled a certain amount of time after you created an account.
  • account inactivity: Accounts are disabled a certain amount of time after the last successful login. This enables you to automatically disable unused accounts.
Disabled accounts are no longer able to log in.
To set up the Account Policy plug-in:
  1. Enable the Account Policy Plug-in.
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn: cn=Account Policy Plugin,cn=plugins,cn=config
    changetype: modify
    replace: nsslapd-pluginEnabled
    nsslapd-pluginEnabled: on
  2. Set the nsslapd-pluginarg0 attribute to point to the plug-in configuration entry.
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn: cn=Account Policy Plugin,cn=plugins,cn=config
    changetype: modify
    replace: nsslapd-pluginarg0
    nsslapd-pluginarg0: cn=config,cn=Account Policy Plugin,cn=plugins,cn=config
  3. Create the plug-in configuration entry.
    • To use CoS or roles with account policies, set the alwaysRecordLogin value to yes. This means every entry has a login time recorded, even if it does not have the acctPolicySubentry attribute.
    • Set the primary attribute to use for the account policy evaluation as value for stateAttrName. For account inactivity, use the lastLoginTime attribute. For a simple account expiration time, use createTimestamp attribute.
    • You can set a secondary attribute in altStateAttrName, that is checked if the primary one defined in stateAttrName does not exist. If no attribute is specified as alternative the default value createTimestamp is used.

      Warning

      If the value for the primary attribute is set to lastLoginTime and altStateAttrName to createTimestamp, users in existing environments are automatically locked out when their accounts do not have the lastLoginTime attribute and the createTimestamp is older than the configured inactivity period.
      To avert this situation, set the alternative attribute to 1.1. This explicitly states to use no attribute as alternative. The lastLoginTime attribute will be created automatically after the user logs in the next time.
    • Set the attribute to use to show which entries have an account policy applied to them (acctPolicySubentry).
    • Set the attribute in the account policy which is used to set the actual timeout period, in seconds (accountInactivityLimit).
    # ldapmodify -a -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn: cn=config,cn=Account Policy Plugin,cn=plugins,cn=config
    
    objectClass: top
    objectClass: extensibleObject
    cn: config
    alwaysRecordLogin: yes
    stateAttrName: lastLoginTime
    altStateAttrName: 1.1
    specattrname: acctPolicySubentry
    limitattrname: accountInactivityLimit
  4. Restart the server to load the new plug-in configuration.
    # systemctl start dirsrv.target
  5. Define an account policy.
    # ldapmodify -a -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn: cn=Account Inactivation Policy,dc=example,dc=com
    
    objectClass: top
    objectClass: ldapsubentry
    objectClass: extensibleObject
    objectClass: accountpolicy
    accountInactivityLimit: 2592000
    cn: Account Inactivation Policy
  6. Create the class of service template entry.
    # ldapmodify -a -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn: cn=TempltCoS,dc=example,dc=com
    
    objectClass: top
    objectClass: ldapsubentry
    objectClass: extensibleObject
    objectClass: cosTemplate
    acctPolicySubentry: cn=Account Inactivation Policy,dc=example,dc=com
    Account policies can be defined directly on user entries, instead of using a CoS. However, using a CoS allows an account policy to be applied and updated reliably for multiple entries and it allows multiple policies to be applied to an entry.
  7. Create the class of service definition entry. The managed entry for the CoS is the account policy attribute, acctPolicySubentry. This example applies the CoS to the entire directory tree.
    # ldapmodify -a -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn: cn=DefnCoS,dc=example,dc=com
    
    objectClass: top
    objectClass: ldapsubentry
    objectclass: cosSuperDefinition
    objectclass: cosPointerDefinition
    cosTemplateDn: cn=TempltCoS,dc=example,dc=com
    cosAttribute: acctPolicySubentry default operational-default

19.9.3. Disabling Accounts a Certain Amount of Time After Password Expiry

Directory Server enables you to configure an account policy that disables an account a certain amount of time after the password expired. Disables accounts are no longer able to log in.
To set up this configuration, follow the procedure in Section 19.9.2, “Account Inactivity and Account Expiration”. However, when configuring the plug-in configuration entry, use the following settings instead:
dn: cn=config,cn=Account Policy Plugin,cn=plugins,cn=config

objectClass: top
objectClass: extensibleObject
cn: config
alwaysrecordlogin: yes
stateAttrName: non_existent_attribute
altStateAttrName: passwordExpirationTime
specattrname: acctPolicySubentry
limitattrname: accountInactivityLimit
This configuration uses a dummy value in the stateAttrName parameter. Therefore, only the passwordExpirationTime attribute set in the altStateAttrName parameter is used to calculate when an account is expired.
To additionally record the time of the last successful login in the lastLoginTime attribute of the user entry, set:
dn: cn=config,cn=Account Policy Plugin,cn=plugins,cn=config

alwaysRecordLoginAttr: lastLoginTime
Using this configuration, an account is automatically disabled if the sum of the time set in the user's passwordExpirationTime attribute and in the accountInactivityLimit parameter's value is in the past. Using this configuration, an account is automatically disabled if the sum of the value in the user's passwordExpirationTime attribute and in the accountInactivityLimit parameter exceeds the time since the alwaysRecordLoginAttr attribute was last updated.

19.9.4. Tracking Login Times without Setting Lockout Policies

It is also possible to use the Account Policy Plug-in to track user login times without setting an expiration time or inactivity period. In this case, the Account Policy Plug-in is used to add the lastLoginTime attribute to user entries, but no other policy rules need to be set.
In that case, set up the Account Policy Plug-in as normal, to track login times. However, do not create a CoS to act on the login information that is being tracked.
  1. Enable the Account Policy Plug-in.
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn: cn=Account Policy Plugin,cn=plugins,cn=config
    changetype: modify
    replace: nsslapd-pluginEnabled
    nsslapd-pluginEnabled: on
  2. Set the nsslapd-pluginarg0 attribute to point to the plug-in configuration entry.
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn: cn=Account Policy Plugin,cn=plugins,cn=config
    changetype: modify
    replace: nsslapd-pluginarg0
    nsslapd-pluginarg0: cn=config,cn=Account Policy Plugin,cn=plugins,cn=config
  3. Create the plug-in configuration entry to record login times.
    • Set the alwaysRecordLogin value to yes so that every entry has a login time recorded.
    • Set the lastLoginTime attribute as the attribute to use for the account policy (stateattrname).
    • Set the attribute to use to show which entries have an account policy applied to them (acctPolicySubentry).
    • Set the attribute in the account policy which is used to set the actual timeout period, in seconds (accountInactivityLimit).
    # ldapmodify -a -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn: cn=config,cn=Account Policy Plugin,cn=plugins,cn=config
    
    objectClass: top
    objectClass: extensibleObject
    cn: config
    alwaysRecordLogin: yes
    stateattrname: lastLoginTime
    altstateattrname: createTimestamp
    specattrname: acctPolicySubentry
    limitattrname: accountInactivityLimit
  4. Restart the server to load the new plug-in configuration.
    # systemctl start dirsrv.target

19.9.5. Unlocking Inactive Accounts

Accounts which are inactivated through the Account Policy Plug-in cannot be managed with the tools that are used to manage lockouts that are set manually by the administrator (ns-activate.pl) or through the password policy.
If an account is locked because it reached the inactivity limit, it can be reactivated by resetting the lastLoginTime attribute. For example:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: uid=jsmith,ou=people,dc=example,dc=com
changetype: modify
replace: lastLoginTime
lastLoginTime: 20160610080000Z

Note

The lastLoginTime is set in GMT/UTC time (Zulu time zone) indicated by the appended Z to the time stamp.

19.10. Replicating Account Lockout Attributes

Account lockout policies will block a user ID from being able to access the Directory Server if the login attempt fails a set number of times. This prevents hackers or other malicious people from illegitimately accessing the Directory Server by guessing a password. Password policies are set locally, and generally account lockout attributes are local to each replica. This means that a person can attempt to log in to one replica until the account lockout count is reached, then try again immediately on another replica. The way to prevent that is to replicate the attributes related to the account lockout counts for an entry, so that the malicious user is locked out of every supplier and consumer replica in the configuration if a login attempt fails on a single master.
By default, three password policy attributes are not replicated, even if other password attributes are. These attributes are related to of login failures and lockout periods:
  • passwordRetryCount
  • retryCountResetTime
  • accountUnlockTime

19.10.1. Managing the Account Lockouts and Replication

Password and account lockout policies are enforced in a replicated environment slightly differently:
  • Password policies are enforced on the data master.
  • Account lockout is enforced on all servers participating in replication.
Some of the password policy information in the directory is replicated automatically:
  • passwordMinAge and passwordMaxAge
  • passwordExp
  • passwordWarning
However, the configuration information is kept locally and is not replicated. This information includes the password syntax and the history of password modifications. Account lockout counters and tiers are not replicated, either, unless specifically configured for replication.
When configuring a password policy in a replicated environment, make sure that these elements are in place, so password policies and account lockout settings are enforced consistently:
  • Warnings from the server of an impending password expiration are issued by all replicas. This information is kept locally on each server, so if a user binds to several replicas in turn, they will be issued the same warning several times. In addition, if the user changes the password, it may take time for this information to filter to the replicas. If a user changes a password and then immediately rebinds, he may find that the bind fails until the replica registers the changes.
  • The same bind behavior should occur on all servers, including suppliers and replicas. Make sure to create the same password policy configuration information on each server.
  • Account lockout counters may not work as expected in a multi-mastered environment. Account lockout counters are not replicated by default (although this can be configured). If account lockout attributes are not replicated at all, then a user could be locked out from one server but could successfully bind to another server (or, conversely, a user may be unlocked on one server and still blocked on another). If account lockout attributes are replicated, then there could be lags between an account lockout change on one server and when that change is propagated to the other servers. It depends on the replication schedule.
  • Entries that are created for replication (for example, the server identities) need to have passwords that never expire. To make sure that these special users have passwords that do not expire, add the passwordExpirationTime attribute to the entry, and give it a value of 20380119031407Z (the top of the valid range).

Note

If the password policy is enabled and the alwaysRecordLogin parameter set to yes, the value of the lastLoginTime attribute can be different on masters and read-only replicas. For example, if a user logs in to a read-only replica, the lastLoginTime attribute is updated locally but the value is not replicated to the master servers.

19.10.2. Configuring Directory Server to Replicate Password Policy Attributes

A special core configuration attribute controls whether password policy operational attributes are replicated. This is the passwordIsGlobalPolicy attribute, which is enabled in the consumer Directory Server configuration to allow the consumer to accept password policy operational attributes.
By default, this attribute is set to off.
To enable these attributes to be replicated, change the passwordIsGlobalPolicy configuration attribute on the consumer:
# ldapmodify -D "cn=Directory Manager" -W -x -h consumer1.example.com

dn: cn=config
changetype: modify
replace: passwordIsGlobalPolicy
passwordIsGlobalPolicy: on
Changing that value to on allows the passwordRetryCount, retryCountResetTime, and accountUnlockTime to be replicated. No other configuration is necessary for the attributes to be included with the replicated attributes.

19.10.3. Configuring Fractional Replication for Password Policy Attributes

Setting the passwordIsGlobalPolicy attribute affects the consumer in replication, in that it allows the consumer to receive updates to those attributes. To control whether the password policy attributes are actually replicated by the supplier, use fractional replication, which controls what specific entry attributes are replicated.
If the password policy attributes should be replicated, then make sure these attributes are included in the fractional replication agreement (as they are by default).
If the passwordIsGlobalPolicy attribute is set to off on the consumer, so no password policy attributes should be replicated, use fractional replication (described in Section 15.1.7, “Replicating a Subset of Attributes with Fractional Replication”) to enforce that on the supplier and specifically exclude those attributes from the replication agreement.
  1. When configuring the replication agreement on the supplier, as described (for example) in Section 15.5.3, “Creating the Replication Agreement”, select the Enable Fractional Replication check box.
  2. By default, every attribute is listed in the Replicated Attributes box. Select the passwordRetryCount, retryCountResetTime, and accountUnlockTime parameters and click the arrow button to move them into the Do Not Replicate box.
  3. Finish configuring the replication agreement.

19.11. Enabling Different Types of Binds

Whenever an entity logs into or accesses the Directory Server, it binds to the directory. There are many different types of bind operation, sometimes depending on the method of binding (such as simple binds or autobind) and some depending on the identity of user binding to the directory (anonymous and unauthenticated binds).
The following sections contain configuration parameters that can increase the security of binds (as in Section 19.11.1, “Requiring Secure Binds”) or streamline bind operations (such as Section 19.11.4, “Configuring Autobind”).

19.11.1. Requiring Secure Binds

A simple bind is when an entity uses a simple bind DN-password combination to authenticate to the Directory Server. Although it is possible to use a password file rather than sending a password directly through the command line, both methods still require sending or accessing a plaintext password over the wire. That makes the password vulnerable to anyone sniffing the connection.
It is possible to require simple binds to occur over a secure connection (TLS or Start TLS), which effectively encrypts the plaintext password as it is sent with the bind operation. (It is also possible to use alternatives to simple binds, such as SASL authentication and certificate-based authentication.)

Important

Along with regular users logging into the server and LDAP operations, server-to-server connections are affected by requiring secure connections for simple binds. Replication, synchronization, and database chaining can all use simple binds between servers, for instance.
Make sure that replication agreements, sync agreements, and chaining configuration specify secure connections if the nsslapd-require-secure-binds attribute is turned on. Otherwise, these operations will fail.

Note

Requiring a secure connection for bind operations only applies to authenticated binds. Bind operations without a password (anonymous and unauthenticated binds) can proceed over standard connections.
  1. Add the nsslapd-require-secure-binds attribute to the cn=config entry:
    # ldapmodify -D "cn=Directory Manager" -W -x
    
    dn: cn=config
    changetype: modify
    replace: nsslapd-require-secure-binds
    nsslapd-require-secure-binds: on
  2. Restart the server.
    # systemctl restart dirsrv.target

19.11.2. Disabling Anonymous Binds

If a user attempts to connect to the Directory Server without supplying any user name or password, this is an anonymous bind. Anonymous binds simplify common search and read operations, like checking the directory for a phone number or email address, by not requiring users to authenticate to the directory first.

Note

By default, anonymous binds are allowed (on) for search and read operations. This allows access to regular directory entries, which includes user and group entries as well as configuration entries like the root DSE. A different option, rootdse, allows anonymous search and read access to search the root DSE itself, but restricts access to all other directory entries.
However, there are risks with anonymous binds. Adequate ACIs must be in place to restrict access to sensitive information and to disallow actions like modifies and deletes. Additionally, anonymous binds can be used for denial of service attacks or for malicious people to gain access to the server.
Section 18.13.1.1.3, “Granting Anonymous Access” has an example on setting ACIs to control what anonymous users can access, and Section 14.1.5, “Setting Resource Limits on Anonymous Binds” has information on placing resource limits for anonymous users.
If those options do not offer a sufficient level of security, then anonymous binds can be disabled entirely.
  1. Add the nsslapd-allow-anonymous-access attribute to the cn=config entry:
    # ldapmodify -D "cn=Directory Manager" -W -x
    
      dn: cn=config
      changetype: modify
      replace: nsslapd-allow-anonymous-access
      nsslapd-allow-anonymous-access: off
  2. Restart the server.
    # systemctl restart dirsrv.target

Note

With anonymous binds disabled, the users cannot log in using their RDN. They are required to provide the full DN to log in.
In addition, when you disable anonymous binds, unauthenticated binds are also disabled automatically.

19.11.3. Allowing Unauthenticated Binds

Unauthenticated binds are connections to Directory Server where a user supplies an empty password. Using the default settings, Directory Server denies access in this scenario for security reasons:
# ldapsearch -w "" -p 389 -h server.example.com -b "dc=example,dc=com" \
     -s sub -x "(objectclass=*)"

ldap_bind: Server is unwilling to perform (53)
	additional info: Unauthenticated binds are not allowed

Warning

Red Hat recommends not enabling unauthenticated binds. This authentication method enables users to bind without supplying a password as any account, including the Directory Manager. After the bind, the user can access all data with the permissions of the account used to bind.
To enable insecure unauthenticated binds, set the nsslapd-allow-unauthenticated-binds to on:
# ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: cn=config
changetype: modify
replace: nsslapd-allow-unauthenticated-binds
nsslapd-allow-unauthenticated-binds: on

19.11.4. Configuring Autobind

Autobind is a way to connect to the Directory Server based on local UNIX credentials, which are mapped to an identity stored in the directory itself. Autobind is configured in two parts:
Before configuring autobind, first make sure that LDAPI is enabled (in Section 1.6, “Enabling LDAPI”). Then, configure the autobind mappings (in Section 19.11.4.2, “Configuring Autobind”).

19.11.4.1. Overview of Autobind and LDAPI

Inter-process communication (IPC) is a way for separate processes on a Unix machine or a network to communicate directly with each other. LDAPI is a way to run LDAP connections over these IPC connections, meaning that LDAP operations can run over Unix sockets. These connections are much faster and more secure than regular LDAP connections.
The Directory Server uses these LDAPI connections to allow users to bind immediately to the Directory Server or to access the Directory Server using tools which support connections over Unix sockets. Autobind uses the uid:gid of the Unix user and maps that user to an entry in the Directory Server, then allows access for that user.
Autobind allows mappings to three directory entries:
  • User entries, if the Unix user matches one user entry
  • Directory Manager (or the super user defined in nsslapd-ldapimaprootdn), if the Unix user is root
Autobind Connection Path

Figure 19.1. Autobind Connection Path

The special autobind users are entries beneath a special autobind suffix (outside the regular user subtree). The entries underneath are identified by their user and group ID numbers:
gidNumber=gid+uidNumberuid, autobindsuffix
If autobind is not enabled but LDAPI is, then Unix users are anonymously bound to the Directory Server, unless they provide other bind credentials.

Note

Autobind allows a client to send a request to the Directory Server without supplying a bind user name and password or using other SASL authentication mechanism. According to the LDAP standard, if bind information is not given with the request, the server processes the request as an anonymous bind. To be compliant with the standard, which requires some kind of bind information, any client that uses autobind should send the request with SASL/EXTERNAL.
For more information on configuring SASL, see Section 9.9, “Setting up SASL Identity Mapping”.

19.11.4.2. Configuring Autobind

Configuring autobind alone allows anonymous access to the Directory Server. It is possible to enable mapping Unix users to entries and also to map root to Directory Manager.
  1. Run ldapmodify to update the Directory Server configuration.
    #ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn: cn=config
    changetype: modify
  2. Enable autobind.
    replace: nsslapd-ldapiautobind
    nsslapd-ldapiautobind: on
  3. To map user entries, add four attributes:
    • nsslapd-ldapimaptoentries to enable entry mapping
    • nsslapd-ldapiuidnumbertype to set the Directory Server attribute to map to the Unix UID number
    • nsslapd-ldapigidnumbertype to set the Directory Server attribute to map to the Unix group ID number
    • nsslapd-ldapientrysearchbase to set the search base to use to find Directory Server user entries
    add: nsslapd-ldapimaptoentries
    nsslapd-ldapimaptoentries: on
    -
    add: nsslapd-ldapiuidnumbertype
    nsslapd-ldapiuidnumbertype: uidNumber
    -
    add: nsslapd-ldapigidnumbertype
    nsslapd-ldapigidnumbertype: gidNumber
    -
    add: nsslapd-ldapientrysearchbase
    nsslapd-ldapientrysearchbase: ou=people,dc=example,dc=com
  4. To map the root entry to Directory Manager, add the nsslapd-ldapimaprootdn attribute:
    add: nsslapd-ldapimaprootdn
    nsslapd-ldapimaprootdn: cn=Directory Manager
  5. Restart the server to apply the new configuration.
    # systemctl restart dirsrv@instance

19.12. Using Pass-Through Authentication

Pass-through authentication (PTA) is a mechanism which allows one Red Hat Directory Server instance to consult another to authenticate bind requests. Pass-through authentication is implement through the PTA Plug-in; when enabled, the plug-in lets a Directory Server instance accept simple bind operations (password-based) for entries not stored in its local database.
Directory Server uses PTA to administer the user and configuration directories on separate instances of Directory Server.
If the configuration directory and the user directory are installed on separate instances of Directory Server, the setup program automatically sets up PTA to allow the Configuration Administrator user (usually admin) to perform administrative duties.
PTA is required in this case because the admin user entry is stored under o=NetscapeRoot suffix in the configuration directory. Therefore, attempts to bind to the user directory as admin would normally fail. PTA allows the user directory to transmit the credentials to the configuration directory, which verifies them. The user directory then allows the admin user to bind.
The user directory in this example acts as the PTA Directory Server, the server that passes through bind requests to another Directory Server. The configuration directory acts as the authenticating directory, the server that contains the entry and verifies the bind credentials of the requesting client.
The pass-through subtree is the subtree not present on the PTA directory. When a user's bind DN contains this subtree, the user's credentials are passed on to the authenticating directory.
Simple Pass-Through Authentication Process

Figure 19.2. Simple Pass-Through Authentication Process

Note

The PTA Plug-in may not be listed in the Directory Server Console if the same server instance is used for the user directory and the configuration directory.
Here's how pass-through authentication works:
  1. The configuration Directory Server (authenticating directory) is installed on machine A. The configuration directory always contains the configuration database and suffix, o=NetscapeRoot. In this example, the server name is configdir.example.com.
  2. The user Directory Server (PTA directory) is then installed on machine B. The user directory stores the root suffix, such as dc=example,dc=com. In this example, the server name is userdir.example.com.
  3. When the user directory is set up on machine B, the setup script prompts for the LDAP URL of the configuration directory on machine A.
  4. The setup program enables the PTA Plug-in and configures it to use the configuration directory LDAP URL.
    This entry contains the LDAP URL for the configuration directory. For example:
    dn: cn=Pass Through Authentication,cn=plugins,
    ...
    nsslapd-pluginEnabled: on
    nsslapd-pluginarg0: ldap://configdir.example.com/o=NetscapeRoot
    ...
    The user directory is now configured to send all bind requests for entries with a DN containing o=NetscapeRoot to the configuration directory configdir.example.com.
  5. When installation is complete, the admin user attempts to connect to the user directory to begin adding users.
  6. The setup program adds the admin user's entry to the directory as uid=admin,ou=TopologyManagement,o=NetscapeRoot. So the user directory passes the bind request through to the configuration directory as defined by the PTA Plug-in configuration.
  7. The configuration directory authenticates the user's credentials and sends the information back to the user directory.
  8. The user directory allows the admin user to bind.

19.12.1. PTA Plug-in Syntax

PTA Plug-in configuration information is specified in the cn=Pass Through Authentication, cn=plugins,cn=config entry on the PTA directory (the user directory configured to pass through bind requests to the authenticating directory) using the required PTA syntax. There are only two attributes in this entry that are significant:
  • nsslapd-pluginEnabled, which sets whether the plug-in is enabled or disabled. The value for this attribute can be on or off.
  • nsslapd-pluginarg0, which points to the configuration directory. The value for this attribute is the LDAP URL of the server and suffix to which to pass the bind requests, along with the optional parameters, maxconns, maxops, timeout, ldver, connlifetime, startTLS.
The variable components of the PTA plug-in syntax are described in Table 19.5, “PTA Plug-in Parameters”.

Note

The LDAP URL (ldap|ldaps://authDS/subtree) must be separated from the optional parameters (maxconns, maxops, timeout, ldver, connlifetime, startTLS) by a single space. If any of the optional parameters are defined, all of them must be defined, even if only the default values are used.
Several authenticating directories or subtrees can be specified by incrementing the nsslapd-pluginarg attribute suffix by one each time, as in Section 19.12.3.2, “Specifying Multiple Authenticating Directory Servers”. For example:
nsslapd-pluginarg0: LDAP URL for the first server
nsslapd-pluginarg1: LDAP URL for the second server
nsslapd-pluginarg2: LDAP URL for the third server
...
The optional parameters are described in the following table in the order in which they appear in the syntax.

Table 19.5. PTA Plug-in Parameters

Variable Definition
state Defines whether the plug-in is enabled or disabled. Acceptable values are on or off.
ldap|ldaps Defines whether TLS is used for communication between the two Directory Servers. See Section 19.12.2.1, “Configuring the Servers to Use a Secure Connection” for more information.
authDS The authenticating directory host name. The port number of the Directory Server can be given by adding a colon and then the port number. For example, ldap://dirserver.example.com:389/. If the port number is not specified, the PTA server attempts to connect using either of the standard ports:
Port 389 if ldap:// is specified in the URL.
Port 636 if ldaps:// is specified in the URL.
See Section 19.12.2.2, “Specifying the Authenticating Directory Server” for more information.
subtree The pass-through subtree. The PTA Directory Server passes through bind requests to the authenticating Directory Server from all clients whose DN is in this subtree. See Section 19.12.2.3, “Specifying the Pass-Through Subtree” for more information. This subtree must not exist on this server. To pass the bind requests for o=NetscapeRoot to the configuration directory, the subtree o=NetscapeRoot must not exist on the server.
maxconns Optional. The maximum number of connections the PTA directory can simultaneously open to the authenticating directory. The default is 3. See Section 19.12.2.4, “Configuring the Optional Parameters” for more information.
maxops Optional. The maximum number of simultaneous operations (usually bind requests) the PTA directory can send to the authenticating directory within a single connection. The default is 5. See Section 19.12.2.4, “Configuring the Optional Parameters” for more information.
timeout Optional. The time limit, in seconds, that the PTA directory waits for a response from the authenticating Directory Server. If this timeout is exceeded, the server returns an error to the client. The default is 300 seconds (five minutes). Specify zero (0) to indicate no time limit should be enforced. See Section 19.12.2.4, “Configuring the Optional Parameters” for more information.
ldver Optional. The version of the LDAP protocol used to connect to the authenticating directory. Directory Server supports LDAP version 2 and 3. The default is version 3, and Red Hat strongly recommends against using LDAPv2, which is old and will be deprecated. See Section 19.12.2.4, “Configuring the Optional Parameters” for more information.
connlifetime Optional. The time limit, in seconds, within which a connection may be used. If a bind request is initiated by a client after this time has expired, the server closes the connection and opens a new connection to the authenticating directory. The server will not close the connection unless a bind request is initiated and the directory determines the connection lifetime has been exceeded. If this option is not specified, or if only one host is listed, no connection lifetime will be enforced. If two or more hosts are listed, the default is 300 seconds (five minutes). See Section 19.12.2.4, “Configuring the Optional Parameters” for more information.
startTLS
Optional. A flag of whether to use Start TLS for the connection to the authenticating directory. Start TLS establishes a secure connection over the standard port, so it is useful for connecting using LDAP instead of LDAPS. The TLS server and CA certificates need to be available on both of the servers.
The default is 0, which is off. To enable Start TLS, set it to 1. To use Start TLS, the LDAP URL must use ldap:, not ldaps:.

19.12.2. Configuring the PTA Plug-in

The only method for configuring the PTA plug-in is to modify the entry cn=Pass Through Authentication,cn=plugins,cn=config. To modify the PTA configuration:
  1. Use the ldapmodify command to modify cn=Pass Through Authentication,cn=plugins,cn=config.
  2. Restart Directory Server.
Before configuring any of the PTA Plug-in parameters, the PTA Plug-in entry must be present in the Directory Server. If this entry does not exist, create it with the appropriate syntax, as described in Section 19.12.1, “PTA Plug-in Syntax”.

Note

If the user and configuration directories are installed on different instances of the directory, the PTA Plug-in entry is automatically added to the user directory's configuration and enabled.
This section provides information about configuring the plug-in in the following sections:

19.12.2.1. Configuring the Servers to Use a Secure Connection

The PTA directory can be configured to communicate with the authenticating directory over TLS by specifying LDAPS in the LDAP URL of the PTA directory. For example:
nsslapd-pluginarg0: ldaps://ldap.example.com:636/o=NetscapeRoot

19.12.2.2. Specifying the Authenticating Directory Server

The authenticating directory contains the bind credentials for the entry with which the client is attempting to bind. The PTA directory passes the bind request to the host defines as the authenticating directory. To specify the authenticating Directory Server, replace authDS in the LDAP URL of the PTA directory with the authenticating directory's host name, as described in Table 19.5, “PTA Plug-in Parameters”.
  1. Use ldapmodify edit the PTA Plug-in entry.
    ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn: cn=Pass Through Authentication,cn=plugins,cn=config
    changetype: modify
    replace: nsslapd-pluginarg0
    nsslapd-pluginarg0: ldap://dirserver.example.com/o=NetscapeRoot
    Optionally, include the port number. If the port number is not given, the PTA Directory Server attempts to connect using either the standard port (389) for ldap:// or the secure port (636) for ldaps://.
    If the connection between the PTA Directory Server and the authenticating Directory Server is broken or the connection cannot be opened, the PTA Directory Server sends the request to the next server specified, if any. There can be multiple authenticating Directory Servers specified, as required, to provide failover if the first Directory Server is unavailable. All of the authentication Directory Server are set in the nsslapd-pluginarg0 attribute.
    Multiple authenticating Directory Servers are listed in a space-separate list of host:port pairs, with this format:
    ldap|ldaps://host1:port1 host2:port2/subtree
  2. Restart the server.
    systemctl restart dirsrv@instance

19.12.2.3. Specifying the Pass-Through Subtree

The PTA directory passes through bind requests to the authenticating directory from all clients with a DN defined in the pass-through subtree. The subtree is specified by replacing the subtree parameter in the LDAP URL of the PTA directory.
The pass-through subtree must not exist in the PTA directory. If it does, the PTA directory attempts to resolve bind requests using its own directory contents and the binds fail.
  1. Use the ldapmodify command to import the LDIF file into the directory.
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn: cn=Pass Through Authentication,cn=plugins,cn=config
    changetype: modify
    replace: nsslapd-pluginarg0
    nsslapd-pluginarg0: ldap://dirserver.example.com/o=NetscapeRoot
    For information on the variable components in this syntax, see Table 19.5, “PTA Plug-in Parameters”.
  2. Restart the server.
    # systemctl restart dirsrv@instance

19.12.2.4. Configuring the Optional Parameters

Additional parameters the control the PTA connection can be set with the LDAP URL.
ldap|ldaps://authDS/subtree maxconns, maxops, timeout, ldver, connlifetime, startTLS
  • The maximum number of connections the PTA Directory Server can open simultaneously to the authenticating directory, represented by maxconns in the PTA syntax. The default value is 3.
  • The maximum number of bind requests the PTA Directory Server can send simultaneously to the authenticating Directory Server within a single connection. In the PTA syntax, this parameter is maxops. The default is value is 5.
  • The time limit for the PTA Directory Server to wait for a response from the authenticating Directory Server. In the PTA syntax, this parameter is timeout. The default value is 300 seconds (five minutes).
  • The version of the LDAP protocol for the PTA Directory Server to use to connect to the authenticating Directory Server. In the PTA syntax, this parameter is ldver. The default is LDAPv3.
  • The time limit in seconds within which a connection may be used. If a bind request is initiated by a client after this time has expired, the server closes the connection and opens a new connection to the authenticating Directory Server. The server will not close the connection unless a bind request is initiated and the server determines the timeout has been exceeded. If this option is not specified or if only one authenticating Directory Server is listed in the authDS parameter, no time limit will be enforced. If two or more hosts are listed, the default is 300 seconds (five minutes). In the PTA syntax, this parameter is connlifetime.
  • Whether to use Start TLS for the connection. Start TLS creates a secure connection over a standard LDAP port. For Start TLS, the servers must have their server and CA certificates installed, but they do not need to be running in TLS.
    The default is 0, which means Start TLS is off. To enable Start TLS, set it to 1. To use Start TLS, the LDAP URL must use ldap:, not ldaps:.
  1. Use ldapmodify to edit the plug-in entry.
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn:  cn=Pass Through Authentication,cn=plugins,cn=config
    changetype: modify
    replace: nsslapd-pluginarg0
    nsslapd-pluginarg0: ldap://dirserver.example.com/o=NetscapeRoot 3,5,300,3,300,0
    (In this example, each of the optional parameters is set to its default value.) Make sure there is a space between the subtree parameter, and the optional parameters.

    Note

    Although these parameters are optional, if any one of them is defined, they all must be defined, even if they use the default values.
  2. Restart the server.
    # systemctl restart dirsrv@instance

19.12.3. PTA Plug-in Syntax Examples

This section contains the following examples of PTA Plug-in syntax in the dse.ldif file:

19.12.3.1. Specifying One Authenticating Directory Server and One Subtree

This example configures the PTA Plug-in to accept all defaults for the optional variables. This configuration causes the PTA Directory Server to connect to the authenticating Directory Server for all bind requests to the o=NetscapeRoot subtree. The host name of the authenticating Directory Server is configdir.example.com.
dn: cn=Pass Through Authentication,cn=plugins,cn=config
...
nsslapd-pluginEnabled: on
nsslapd-pluginarg0: ldap://configdir.example.com/o=NetscapeRoot
...

19.12.3.2. Specifying Multiple Authenticating Directory Servers

If the connection between the PTA Directory Server and the authenticating Directory Server is broken or the connection cannot be opened, the PTA Directory Server sends the request to the next server specified, if any. There can be multiple authenticating Directory Servers specified, as required, to provide failover if the first Directory Server is unavailable. All of the authentication Directory Server are set in the nsslapd-pluginarg0 attribute. Multiple authenticating Directory Servers are listed in a space-separate list of host:port pairs. For example:
dn: cn=Pass Through Authentication,cn=plugins,cn=config
...	
nsslapd-pluginEnabled: on
nsslapd-pluginarg0: ldap://configdir.example.com:389 config2dir.example.com:1389/o=NetscapeRoot 
...

Note

The nsslapd-pluginarg0 attribute sets the authentication Directory Server; additional nsslapd-pluginargN attributes can set additional suffixes for the PTA Plug-in to use, but not additional hosts.

19.12.3.3. Specifying One Authenticating Directory Server and Multiple Subtrees

The following example configures the PTA Directory Server to pass through bind requests for more than one subtree (using parameter defaults):
dn: cn=Pass Through Authentication,cn=plugins,cn=config
...	
nsslapd-pluginEnabled: on
nsslapd-pluginarg0: ldap://configdir.example.com/o=NetscapeRoot
nsslapd-pluginarg1: ldap://configdir.example.com/dc=example,dc=com
...

19.12.3.4. Using Non-Default Parameter Values

This example uses a non-default value (10) only for the maximum number of connections parameter maxconns. Each of the other parameters is set to its default value. However, because one parameter is specified, all parameters must be defined explicitly in the syntax.
dn: cn=Pass Through Authentication,cn=plugins,cn=config
...	
nsslapd-pluginEnabled: on
nsslapd-pluginarg0: ldap://configdir.example.com/o=NetscapeRoot 10,5,300,3,300,1
...

19.12.3.5. Specifying Different Optional Parameters and Subtrees for Different Authenticating Directory Servers

To specify a different pass-through subtree and optional parameter values for each authenticating Directory Server, set more than one LDAP URL/optional parameters pair. Separate the LDAP URL/optional parameter pairs with a single space as follows.
dn: cn=Pass Through Authentication,cn=plugins,cn=config
...
nsslapd-pluginEnabled: on
nsslapd-pluginarg0:ldap://configdir.example.com/o=NetscapeRoot 10,15,30,3,600,0
nsslapd-pluginarg1:ldap://config2dir.example.com/dc=example,dc=com 7,7,300,3,300,1
...

19.13. Using Active Directory-formatted User Names for Authentication

When you connect to Directory Server, you must specify the distinguished name (DN) of the user, such as uid=user_name,ou=People,dc=example,dc=com, to authenticate. However, the DN can be difficult to remember. If you enable and configure the AD DN plug-in, you can use Active Directory-formatted user names, such as user_name or user_name@domain instead of the DN.
After you enable the plug-in and a user connects to the directory using a user name that is not DN-formatted, Directory Server searches the DN based on the plug-in's configuration. If the search returns one DN, Directory Server uses this DN for the authentication. If none or multiple DNs are returned, authentication fails.

Note

You can only enable and configure the AD DN plug-in using the command line.
To enable and configure the plug-in it to use example.com as the default domain:
  1. Add the cn=addn,cn=plugins,cn=config plug-in entry and set the default domain:
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    dn: cn=addn,cn=plugins,cn=config
    changetype: add
    objectClass: top
    objectClass: nsSlapdPlugin
    objectClass: extensibleObject
    cn: addn
    nsslapd-pluginPath: libaddn-plugin
    nsslapd-pluginInitfunc: addn_init
    nsslapd-pluginType: preoperation
    nsslapd-pluginEnabled: on
    nsslapd-pluginId: addn
    nsslapd-pluginVendor: 389 Project
    nsslapd-pluginVersion: 1.3.6.0
    nsslapd-pluginDescription: Allow AD DN style bind names to LDAP
    addn_default_domain: example.com
    The required addn_default_domain parameter in the plug-in entry sets the default domain. The plug-in appends this domain if the specified user name during an authentication does not contain a domain name.
  2. Add a configuration entry for the default domain:
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    dn: cn=example.com,cn=addn,cn=plugins,cn=config
    changetype: add
    objectClass: top
    objectClass: extensibleObject
    cn: example.com
    addn_base: ou=People,dc=example,dc=com
    addn_filter: (&(objectClass=account)(uid=%s))
    For details about the parameters used in the example, see their descriptions in the Red Hat Directory Server Configuration, Command, and File Reference.

    Warning

    You must add at least a configuration entry for the default domain. If the entry is missing, Directory Server fails to start.
  3. Optionally, you can create additional domain configurations as described in the previous step to support multiple domain names. Each domain configuration can use a different search base and filter.
  4. Restart the Directory Server instance:
    # systemctl restart dirsrv@instance_name

19.14. Using PAM for Pass-Through Authentication

Pass-through authentication is when any authentication request is forwarded from one server to another service.
Many systems already have authentication mechanisms in place for Unix and Linux users. One of the most common authentication frameworks is Pluggable Authentication Modules (PAM). Since many networks already existing authentication services available, administrators may want to continue using those services. A PAM module can be configured to tell Directory Server to use an existing authentication store for LDAP clients.
PAM pass-through authentication in Red Hat Directory Server uses the PAM Pass-Through Authentication Plug-in, which enables the Directory Server to talk to the PAM service to authenticate LDAP clients.
PAM Pass-Through Authentication Process

Figure 19.3. PAM Pass-Through Authentication Process

Note

PAM pass-through authentication works together with account inactivation when authenticating users, assuming that the appropriate mapping method (ENTRY) is used. However, PAM pass-through authentication does not validate passwords against password policies set either globally or locally, because the passwords are set and stored in the PAM module, not in the Directory Server.

19.14.1. PAM Pass-Through Authentication Configuration Options

PAM pass-through authentication is configured in child entries beneath the PAM Pass-Through Authentication plug-in container entry. There can be multiple PAM pass-through authentication policies, applied to different suffixes or to different entries within suffixes.
There are several different areas that can be configured for PAM pass-through:
  • The suffixes that are controlled by the PAM pass-through authentication plug-in. This covers suffixes to exclude, suffixes to include, and how to handle a missing suffix.
  • Individual entries within the configured suffixes which are the target of the authentication configuration. By default, all entries within a suffix are included in the authentication scope, but it is possible to configure multiple, different PAM Pass-Through Auth plug-in instances and then apply different plug-in configuration to different users.
  • The PAM attribute mapping. The credentials that are offered to the Directory Server have to be mapped in some way to an LDAP entry and then, back to the credentials in the PAM service. This is done by defining a mapping method and then, optionally, which LDAP attribute to use to match the credentials.
  • General configuration such as using TLS connections, the PAM service to use, and whether to fallback to LDAP authentication if PAM authentication fails.

Note

There can be multiple configuration instances of the PAM Pass-Through Authentication plug-in. An instance of the PAM Pass-Through Authentication plug-in can be applied to a subset of user entries by using the pamFilter attribute to set an LDAP filter to search for the specific entries to use with the plug-in.
For a list of attributes you can set, see the PAM Pass Through Auth Plug-in Attributes section in the Red Hat Directory Server Configuration, Command, and File Reference.

19.14.1.1. Specifying the Suffixes to Target for PAM PTA

The PAM PTA plug-in is applied globally, to all suffixes, by default unless they are explicitly excluded. Excluding and including suffixes can help target what areas in the directory use PAM authentication instead of LDAP authentication.

Note

The target of a PAM pass-through authentication entry must be a suffix, not an arbitrary subtree. As described in Section 2.1, “Creating and Maintaining Suffixes”, a suffix is a subtree which is associated with a specific back end database, such as cn=config which is associated with NetscapeRoot or the root suffix dc=example,dc=com which is associated with userRoot.
The pamExcludeSuffix attribute excludes a suffix. By default, only the configuration subtree (cn=config) is excluded. Alternatively, the PAM PTA plug-in can be applied to a suffix with the pamIncludeSuffix attribute. Both of these attributes are multi-valued.
If the include attribute is set, for example, all other suffixes are automatically excluded. Likewise, if an exclude attribute is set, all other suffixes are automatically included.
pamExcludeSuffix: cn=config
pamExcludeSuffix: o=NetscapeRoot
With pamIncludeSuffix, only the given suffix is included and all others are automatically excluded. Since this attribute is multi-valued, more than one suffix can be included in the PAM evaluation by explicitly listing the suffixes.
pamIncludeSuffix: ou=Engineering,dc=example,dc=com
pamIncludeSuffix: ou=QE,dc=example,dc=com
The pamMissingSuffix attribute tells the server how to handle a failure if the specified suffix (include or exclude) does not exist. If it is set to IGNORE, then if the suffix does not exist, the plug-in simply skips that suffix and tries the next.
pamMissingSuffix: IGNORE
pamIncludeSuffix: ou=Engineering,dc=example,dc=com
pamIncludeSuffix: ou=Not Real,dc=example,dc=com

19.14.1.2. Applying Different PAM Pass-Through Authentication Configurations to Different Entries

By default, a PAM pass-through authentication policy applies to all entries within the designated suffixes. However, it is possible to specify an LDAP filter in the pamFilter attribute which identifies specific entries within the suffix to which to apply the PAM pass-through authentication policy.
This is useful for applying different PAM configurations or mapping methods to different user types, using multiple PAM pass-through authentication policies.

19.14.1.3. Setting PAM PTA Mappings

There has to be a way to connect the LDAP identity to the PAM identity. The first thing to define is the method to use to map the entries. There are three options: DN, RDN, and ENTRY. ENTRY uses a user-defined attribute in the entry.
Multiple mapping methods can be supplied in an ordered, space-separated list. The plug-in attempts to use each mapping method in the order listed until authentication succeeds or until it reaches the end of the list.
For example, this mapping method first maps the RDN method, then ENTRY, then DN, in the order the methods are listed:
pamIDMapMethod: RDN ENTRY DN
The different mapping methods are listed in Table 19.6, “Mapping Methods for PAM Authentication”.

Note

Directory Server user account inactivation is only validated using the ENTRY mapping method. With RDN or DN, a Directory Server user whose account is inactivated can still bind to the server successfully.

Table 19.6. Mapping Methods for PAM Authentication

Mapping Description
RDN This method uses the value from the leftmost RDN in the bind DN. The mapping for this method is defined by Directory Server. This is the default mapping method, if none is given.
ENTRY This method pulls the value of the PAM identity from a user-defined attribute in the bind DN entry. The identity attribute is defined in the pamIDAttr attribute. For example: pamIDAttr: customPamUid
DN This method uses the full distinguished name from the bind DN. The mapping for this method is defined by Directory Server.

19.14.1.4. Configuring General PAM PTA Settings

Three general configuration settings can be set for PAM authentication:
  • The service name to send to PAM (pamService); this is the name of the configuration file to use in /etc/pam.d
  • Whether to require a secure connection (pamSecure)
  • Whether to fall back to LDAP authentication if PAM authentication fails (pamFallback)
pamFallback: false
pamSecure: false
pamService: ldapserver

19.14.2. Configuring PAM Pass-Through Authentication

Note

There can be multiple configuration instances of the PAM Pass-Through Authentication plug-in. An instance of the PAM Pass-Through Authentication plug-in can be applied to a subset of user entries by using the pamFilter attribute to set an LDAP filter to search for the specific entries to use with the plug-in.
PAM pass-through authentication is configured through the command line.
  1. Make sure the PAM service is fully configured.
  2. Remove the pam_fprintd.so module from the PAM configuration file.

    Important

    The pam_fprintd.so module cannot be in the configuration file referenced by the pamService attribute of the PAM Pass-Through Authentication Plug-in configuration. Using the PAM fprintd module causes the Directory Server to hit the max file descriptor limit and can cause the Directory Server process to abort.
  3. Enable the plug-in; this is disabled by default.
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn: cn=PAM Pass-Through Auth Plugin,cn=plugins,cn=config
    changetype: modify
    replace: nsslapd-pluginEnabled
    nsslapd-pluginEnabled: on
  4. Create the PAM Pass-Through Auth plug-in configuration entry.
    # ldapmodify -a -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn: cn=Admin PAM PTA Config,cn=PAM Pass-Through Auth Plugin,cn=plugins,cn=config
    cn: AD PAM PTA Config
  5. Add the attributes available for the PAM plug-in. The available attributes are listed in Section 19.14.1, “PAM Pass-Through Authentication Configuration Options”, and Example 19.2, “Example PAM Pass-Through Authentication Configuration Entry” has an example entry.
  6. Restart the server to load the new plug-in configuration.
    # systemctl restart dirsrv.target

Example 19.2. Example PAM Pass-Through Authentication Configuration Entry

 dn: cn=Admin PAM PTA Config,cn=PAM Pass Through Auth,cn=plugins,cn=config
 objectclass: top
 objectclass: pamConfig
 objectClass: nsSlapdPlugin
 objectClass: extensibleObject
 cn: Admin PAM PTA Config
 pamMissingSuffix: ALLOW
 pamExcludeSuffix: cn=config  
 pamExcludeSuffix: o=NetscapeRoot  
 pamIDMapMethod: RDN ENTRY  
 pamIDAttr: customPamUid  
 pamFilter: (manager=uid=bjensen,ou=people,dc=example,dc=com)  
 pamFallback: FALSE
 pamSecure: TRUE  
 pamService: ldapserver

19.14.3. Using PAM Pass-Through Authentication with Active Directory as the Backend

PAM pass-through authentication forwards the credentials from the Directory Server to the PAM service. One option is to set up and configure PAM modules specifically for Directory Server. Another option — and one which may be more repeatable and more convenient in some infrastructures — is to use the System Security Services Daemon (SSSD) to configure PAM. Because SSSD can use a variety of different identity stores, a lot of different servers or services can be used to provide credentials, including Active Directory.
Using pass-through authentication through SSSD is a daisy chain of services. The PAM PTA Plug-in is configured as normal. It points to the given PAM service file to use. This service file is managed by SSSD, and SSSD is configured to connect with whatever identity provider is required, even multiple providers.
PAM Pass-Through Authentication with SSSD

Figure 19.4. PAM Pass-Through Authentication with SSSD

For more information on SSSD, see the Red Hat Enterprise Linux 6 Deployment Guide.
To configure PAM pass-through authentication with Active Directory:
  1. Configure SSSD to use the Active Directory server as one of its identity providers.
    This configuration is covered in the Red Hat Enterprise Linux 6 Deployment Guide.
  2. Enable the PAM Pass-Through Auth plug-in; this is disabled by default.
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn: cn=PAM Pass-Through Auth Plugin,cn=plugins,cn=config
    changetype: modify
    replace: nsslapd-pluginEnabled
    nsslapd-pluginEnabled: on
  3. Create the PAM Pass-Through Auth plug-in configuration entry.
    # ldapmodify -a -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn: cn=AD PAM PTA Config,cn=PAM Pass-Through Auth Plugin,cn=plugins,cn=config
    cn: AD PAM PTA Config
  4. Set the pamService attribute to point to the PAM configuration file managed by SSSD. By default, this is /etc/pam.d/system-auth.
    pamService: system-auth

    Important

    The pam_fprintd.so module cannot be in the configuration file referenced by the pamService attribute of the PAM Pass-Through Authentication Plug-in configuration. Using the PAM fprintd module causes the Directory Server to hit the max file descriptor limit and can cause the Directory Server process to abort.
  5. Configure the ID map method and attribute. There are several options for how this can be done, depending on the Directory Server environment.
    The simplest is to use the RDN map method, which automatically uses the uid attribute (or the correct naming attribute) to map Directory Server users back to Active Directory users (since Active Directory is the identity provider).
    pamIDMapMethod: RDN
    Similarly, this can be accomplished with the ENTRY map method by using the samAccountName attribute. If the user accounts in Directory Server are created with uids that match the samAccountName value for the user account in Active Directory, then the mapping is successful.
    pamIDMapMethod: ENTRY
    pamIDAttr: samAccountName
    If Windows synchronization is configured, then the ENTRY method can be used with the ntUserDomainId attribute. The Directory Server and Active Directory user accounts are already synced, based on that attribute value, so the PAM mapping is successful.
    pamIDMapMethod: ENTRY
    pamIDAttr: ntUserDomainId
  6. Restart the server to load the plug-in configuration.
    # systemctl restart dirsrv.target

19.15. Manually Inactivating Users and Roles

A single user account or set of accounts can be temporarily inactivated. Once an account is inactivated, a user cannot bind to the directory. The authentication operation will fail.
Users and roles are inactivated using the operational attribute nsAccountLock. When an entry contains the nsAccountLock attribute with a value of true, the server rejects the bind.
The same procedures are used to inactivate users and roles. However, when a role is inactivated, the members of the role are inactivated, not the role entry itself. For more information about roles in general and how roles interact with access control in particular, see Chapter 8, Organizing and Grouping Entries.

Warning

The root entry (the entry corresponding to the root or sub suffix) on a database cannot be inactivated. Chapter 3, Managing Directory Entries has information on creating the entry for a root or sub suffix, and Chapter 2, Configuring Directory Databases has information on creating root and sub suffixes.

19.15.1. Viewing Inactive Users and Roles Using the Console

  1. Select the View menu, and select the Display item.
  2. Select the Inactivation State item.
When the inactivation state is visible, any inactive object is listed in the right pane of the Console with a red slash through it.

19.15.2. Activating and Inactivating Users and Roles Using the Console

All user and role entries are active by default. They must be manually marked inactive and, once inactivated, must be manually re-activated.
  1. Select the Directory tab.
  2. Browse the navigation tree in the left navigation pane, and double-click the entry to inactivate.
    The Edit Entry dialog box appears.
  3. Click Account in the left pane. The right pane states that the role or user is activate. Click the Inactivate button to inactivate the user or role (or the Activate button, to re-enable the entry).
  4. Click OK.
Alternatively, highlight the entry and select Inactivate (or Activate, if appropriate) from the Object menu.

19.15.3. Viewing Inactive Users and Roles Using the Command Line

The ns-accountstatus.pl script is used to obtain detailed information about active and inactive users.
To obtain the account status of a single user, you can use the command as follows:
# ns-accountstatus.pl -D "cn=Directory Manager" -w password -I "uid=jsmith,ou=people,dc=example,dc=com"
uid=bjensen,ou=people,dc=example,dc=com  activated.
Add the -V option to obtain more verbose output:
# ns-accountstatus.pl -D "cn=Directory Manager" -w password -I "uid=jsmith,ou=people,dc=example,dc=com"
Entry:                   uid=jsmith,ou=People,dc=example,dc=com
Entry Creation Date:     20160204153140Z (02/04/2016 10:31:40)
Entry Modification Date: 20160205163904Z (02/05/2016 11:39:04)
Last Login Date:         20160205163905Z (02/05/2016 11:39:05)
Inactivity Limit:        2592000 seconds (30 days)
Time Until Inactive:     2591688 seconds (29 days, 23 hours, 54 minutes, 48 seconds)
Time Since Inactive:     -
Entry State:             activated
The above is an example of an active account, as indicated by the last three lines of the output. An inactivated account would instead provide output similar to the following:
# ns-accountstatus.pl -D "cn=Directory Manager" -w password -I "uid=jsmith,ou=people,dc=example,dc=com"
Entry:                   uid=jsmith,ou=people,dc=example,dc=com
Entry Creation Date:     20160204153140Z (02/04/2016 10:31:40)
Entry Modification Date: 20160204160545Z (02/04/2016 11:05:45)
Last Login Date:         20160204160546Z (01/04/2016 11:05:46)
Inactivity Limit:        2592000 seconds (30 days)
Time Until Inactive:     -
Time Since Inactivated:  85877 seconds (23 hours, 51 minutes, 17 seconds)
Entry State:             inactivated (inactivity limit exceeded)
Instead of using the -I option to specify an account, you can use the -b (search a database suffix), -f (use a filter), and -s (search scope) options to create a search. Additionally, you can refine the search by using the -i option (return only inactive accounts) or the -g X option (return only accounts which will expire in the next X seconds). For example:
# ns-accountstatus.pl -D "cn=Directory Manager" -w password -b "ou=people,dc=example,dc=com" -f "(uid=*)" -V -g 86400
Entry:                   uid=jsmith,ou=people,dc=example,dc=com
Entry Creation Date:     20160204153140Z (02/04/2016 10:31:40)
Entry Modification Date: 20160205163904Z (02/05/2016 11:39:04)
Last Login Date:         20160205163905Z (01/05/2016 11:39:05)
Inactivity Limit:        2592000 seconds (30 days)
Time Until Inactive:     979 seconds (16 minutes, 19 seconds)
Time Since Inactive:     -
Entry State:             activated
As you can see from the last three lines of the output, this account is currently active, but will expire soon.

19.15.4. Inactivating and Activating Users and Roles Using the Command Line

The Directory Server uses dual scripts to inactivate or activate entries through the command line. The ns-inactivate.pl and ns-activate.pl script share similar options to identify the entry to modify, as listed in the Red Hat Directory Server Configuration, Command, and File Reference.
For example, to inactivate a user account:
[root@server ~]# ns-inactivate.pl -Z instance_name -D Directory Manager -w secret -p 389 -h example.com  -I "uid=jfrasier,ou=people,dc=example,dc=com"
Then, the account can be re-activated:
# ns-activate.pl -Z instance_name -D Directory Manager -w secret -p 389 -h example.com  -I "uid=jfrasier,ou=people,dc=example,dc=com"

Chapter 20. Monitoring Server and Database Activity

This chapter describes monitoring database and Red Hat Directory Server logs. For information on using SNMP to monitor the Directory Server, see Chapter 21, Monitoring Directory Server Using SNMP.

20.1. Types of Directory Server Log Files

Directory Server provides the following log types:
  • Access log: Contains information on client connections and connection attempts to the Directory Server instance. This log type is enabled by default.
  • Error log: Contains detailed messages of errors and events the directory experiences during normal operations. This log type is enabled by default.

    Warning

    If the Directory Server fails to write to the errors log, the server sends an error message to the Syslog service and exits. This log type is enabled by default.
  • Audit log: Records changes made to each database as well as to server configuration. This log is not enabled by default.
  • Audit fail log: Records failed audit events. This log is not enabled by default.

20.2. Displaying Log Files

You can display the Directory Server log files using the command line and Directory Server Console.

20.2.1. Displaying Log Files Using the Command Line

To display the log files using the command line, use the utilities included in Red Hat Enterprise Linux, such as less, more, and cat. For example:
# less /var/log/dirsrv/slapd-instance_name/access
To display the locations of log files:
# ldapsearch -D "cn=Directory Manager" -W -p 389 \
     -h server.example.com -x -b "cn=config" -s base \
     nsslapd-accesslog nsslapd-errorlog nsslapd-auditlog nsslapd-auditfaillog
...
nsslapd-accesslog: /var/log/dirsrv/slapd-instance_name/access
nsslapd-errorlog: /var/log/dirsrv/slapd-instance_name/errors
nsslapd-auditlog: /var/log/dirsrv/slapd-instance_name/audit
nsslapd-auditfaillog: /var/log/dirsrv/slapd-instance_name/audit-failure

Note

If logging for a log type is not enabled, the corresponding log file does not exist.

20.2.2. Displaying Log Files Using the Console

To display the Directory Server log files:
  1. Open the Directory Server Console. For details, see Section 1.3.1, “Opening the Directory Server Console”.
  2. Select the Status tab.
  3. Expand the Logs entry and select the log you want to display.

    Note

    The Console does not contain a log file viewer for the Audit Fail log. Alternatively, you can:
  4. Optionally, you can apply the following settings to the log file viewer:
    • Set the number of line to display in the Lines to show field.
    • Set a filter in the Show only lines containing field.
    • Display older log files of the same type, by selecting the log in the Select log field.
    • Enable automatically displaying new log entries by selecting Continuous refresh.
    Click the Refresh button to apply the changes.

20.3. Configuring Log Files

For all types of log files, the log creation and log deletion policies have to be configured. The log creation policy sets when a new log file is started, and the log deletion policy sets when an old log file is deleted.

20.3.1. Enabling or Disabling Logs

The access and error logging is enabled by default. However, audit and audit fail logging is disabled by default.

Note

Disabling the access logging can be useful in some scenarios, because every 2000 accesses to the directory increases the log file by approximately 1 megabyte. However, before turning off access logging, consider that this information can help troubleshooting problems.

Enabling or Disabling Logging in the Directory Server Console

  1. Log in to the Directory Server Console.
  2. Select the Configuration tab.
  3. In the navigation tree, expand the Logs folder, and select the folder for the log to enable or disable.
  4. To enable or disable logging, select the Enable Logging check box.
  5. If the log is being enabled, enter the full path and file name for the Directory Server to use for logging in the field provided. The default path is /var/log/dirsrv/slapd-instance/log_type, such as /var/log/dirsrv/slapd-instance/access.
  6. Click Save.

Enabling or Disabling Logging Using the Command Line

You can use the ldapmodify utility to modify the parameters in the cn=config subtree that control the Directory Server logging feature:
  • Access log: nsslapd-accesslog-logging-enabled
  • Error log: nsslapd-errorlog-logging-enabled
  • Audit log: nsslapd-auditlog-logging-enabled
  • Audit fail log: nsslapd-auditfaillog-logging-enabled
For further details, see the corresponding section in the Red Hat Directory Server Configuration, Command, and File Reference.
For example, to enable audit logging, enter:
# ldapmodify -D "cn=Directory Manager" -W -x
dn: cn=config
changetype: modify
replace: nsslapd-auditlog-logging-enabled
nsslapd-auditlog-logging-enabled: on

20.3.2. Configuring Plug-in-specific Logging

For debugging, you can enable access and audit logging for operations a plug-ins executes. For details, see the nsslapd-logAccess and nsslapd-logAudit parameter in the corresponding section in the Red Hat Directory Server Configuration, Command, and File Reference.

20.3.3. Disabling High-resolution Log Time Stamps

Using the default settings, Directory Server logs entries with nanosecond precision:
[27/May/2016:17:52:04.754335904 -0500] schemareload - Schema validation passed.
[27/May/2016:17:52:04.894255328 -0500] schemareload - Schema reload task finished.
To disable high-resolution log time stamps:
# ldapmodify -D "cn=Directory Manager" -W -x
dn: cn=config
changetype: modify
replace: nsslapd-logging-hr-timestamps-enabled
nsslapd-logging-hr-timestamps-enabled: off

Note

The option to disable high-resolution log time stamps is deprecated and will be removed in a future release.
After disabling high-resolution log time stamps, Directory Server logs with second precision only:
[27/May/2016:17:52:04 -0500] schemareload - Schema validation passed.
[27/May/2016:17:52:04 -0500] schemareload - Schema reload task finished.

20.3.4. Defining a Log File Rotation Policy

To periodically archive the current log file and create a new one, set a log file rotation policy. You can update the settings in the cn=config subtree using the Directory Server Console or command line.
You can set the following configuration parameters to control the log file rotation policy:
Access mode
The access mode sets the file permissions on newly created log files.
  • Access log: nsslapd-accesslog-mode
  • Error log: nsslapd-errorlog-mode
  • Audit log: nsslapd-auditlog-mode
  • Audit fail log: nsslapd-auditfaillog-mode
Maximum number of logs
Sets the maximum number of log files to keep. When the number of files is reached, Directory Server deletes the oldest log file before creating the new one.
  • Access log: nsslapd-accesslog-maxlogsperdir
  • Error log: nsslapd-errorlog-maxlogsperdir
  • Audit log: nsslapd-auditlog-maxlogsperdir
  • Audit fail log: nsslapd-auditfaillog-maxlogsperdir
File size for each log
Sets the maximum size of a log file in megabytes before it is rotated.
  • Access log: nsslapd-accesslog-maxlogsize
  • Error log: nsslapd-errorlog-maxlogsize
  • Audit log: nsslapd-auditlog-maxlogsize
  • Audit fail log: nsslapd-auditfaillog-maxlogsize
Create a log every
Sets the maximum age of a log file.
  • nsslapd-accesslog-logrotationtime and nsslapd-accesslog-logrotationtimeunit
  • nsslapd-errorlog-logrotationtime and nsslapd-errorlog-logrotationtimeunit
  • nsslapd-auditlog-logrotationtime and nsslapd-auditlog-logrotationtimeunit
  • nsslapd-auditfaillog-logrotationtime and nsslapd-auditfaillog-logrotationtimeunit
Additionally, you can set the time when the log file is rotated using the following parameters:
  • nsslapd-accesslog-logrotationsynchour and nsslapd-accesslog-logrotationsyncmin
  • nsslapd-errorlog-logrotationsynchour and nsslapd-errorlog-logrotationsyncmin
  • nsslapd-auditlog-logrotationsynchour and nsslapd-auditlog-logrotationsyncmin
  • nsslapd-auditfaillog-logrotationsynchour and nsslapd-auditfaillog-logrotationsyncmin
For details, see the parameter descriptions in the corresponding section in the Red Hat Directory Server Configuration, Command, and File Reference.
Each log file starts with a title, which identifies the server version, host name, and port, for ease of archiving or exchanging log files. For example:
389-Directory/1.3.5.10 B2016.257.1817
server.example.com:389 (/etc/dirsrv/slapd-instance)

Configuring Log File Rotation in the Directory Server Console

  1. Log in to the Directory Server Console.
  2. Select the Configuration tab.
  3. In the navigation tree, expand the Logs folder, and select the folder for the log you want to update the settings.
  4. Set the logging settings in the Creation policy area. For example:
  5. Click Save.

Configuring Log File Rotation Using the Command Line

You can use the ldapmodify utility to modify the parameters controlling the Directory Server logging features. For example for the error log, to set access mode 600, to keep maximum 2, and to rotate log files at a size of 100 MB or every 5 days, run:
# ldapmodify -D "cn=Directory Manager" -W -x
dn: cn=config
changetype: modify
replace: nsslapd-errorlog-mode
nsslapd-errorlog-mode: 600
-
replace: nsslapd-errorlog-maxlogsperdir
nsslapd-errorlog-maxlogsperdir: 2
-
replace: nsslapd-errorlog-maxlogsize
nsslapd-errorlog-maxlogsize: 100
-
replace: nsslapd-errorlog-logrotationtime
nsslapd-errorlog-logrotationtime: 5
-
replace: nsslapd-errorlog-logrotationtimeunit
nsslapd-errorlog-logrotationtimeunit: day

20.3.5. Defining a Log File Deletion Policy

Directory Server automatically deletes old archived log files, if you set a Deletion Policy.

Note

You can only set a log file deletion policy if you have a log file rotation policy set. Directory Server applies the deletion policy at the time of log rotation.
You can set the following configuration parameters to control the log file deletion policy:
Total log size
If the size of all access, error, audit or audit fail log files increases the configured value, the oldest log file is automatically deleted.
  • Access log: nsslapd-accesslog-logmaxdiskspace
  • Error log: nsslapd-errorlog-logmaxdiskspace
  • Audit log: nsslapd-auditlog-logmaxdiskspace
  • Audit log: nsslapd-auditfaillog-logmaxdiskspace
Free disk space is less than
When the free disk space reaches this value, the oldest archived log file is automatically deleted.
  • Access log: nsslapd-accesslog-logminfreediskspace
  • Error log: nsslapd-errorlog-logminfreediskspace
  • Audit log: nsslapd-auditlog-logminfreediskspace
  • Audit log: nsslapd-auditfaillog-logminfreediskspace
When a file is older than a specified time
When a log file is older than the configured time, it is automatically deleted.
  • Access log: nsslapd-accesslog-logexpirationtime and nsslapd-accesslog-logexpirationtimeunit
  • Error log: nsslapd-errorlog-logminfreediskspace and nsslapd-errorlog-logexpirationtimeunit
  • Audit log: nsslapd-auditlog-logminfreediskspace and nsslapd-auditlog-logexpirationtimeunit
  • Audit log: nsslapd-auditfaillog-logminfreediskspace and nsslapd-auditfaillog-logexpirationtimeunit
For further details, see the corresponding section in the Red Hat Directory Server Configuration, Command, and File Reference.

Configuring a Log Deletion Policy in the Directory Server Console

  1. Log in to the Directory Server Console.
  2. Select the Configuration tab.
  3. In the navigation tree, expand the Logs folder, and select the folder for the log you want to update the settings.
  4. Set the logging settings in the Deletion Policy area. For example:
  5. Click Save.

Configuring Log Deletion Policy Using the Command Line

You can use the ldapmodify utility modify the parameters controlling the Directory Server logging features. For example, to auto-delete the oldest access log file if the total size of all access log files increases 500 MB, run:
# ldapmodify -D "cn=Directory Manager" -W -x
dn: cn=config
changetype: modify
replace: nsslapd-accesslog-logmaxdiskspace
nsslapd-accesslog-logmaxdiskspace: 500

20.3.6. Manual Log File Rotation

The Directory Server supports automatic log file rotation for all three logs. However, it is possible to rotate log files manually if there are no automatic log file creation or deletion policies configured. By default, access, error, audit and audit fail log files can be found in the following location:
/var/log/dirsrv/slapd-instance
To rotate log files manually:
  1. Shut down the server.
    # systemctl stop dirsrv.target instance
  2. Move or rename the log file being rotated so that the old log file is available for future reference.
  3. Restart the server.
    # systemctl restart dirsrv.target instance

20.3.7. Configuring Log Levels

Both the access and the error log can record different amounts of information, depending on the log level that is set.
You can set the following configuration parameters to control the log levels for the:
  • Access log: nsslapd-accesslog-level
  • Error log: nsslapd-errorlog-level
For further details and a list of the supported log levels, see the corresponding section in the Red Hat Directory Server Configuration, Command, and File Reference.

Note

Changing the log level from the default can cause the log file to grow very rapidly. Red Hat recommends not to change the default values without being asked to do so by the Red Hat technical support.

Configuring the Log Level in the Directory Server Console

  1. Log in to the Directory Server Console.
  2. Select the Configuration tab.
  3. In the navigation tree, expand the Logs folder, and select the folder for the log you want to update the settings.
  4. Set the log level in the Log Level area. For example, for the error log file
  5. Click Save.

Configuring the Log Level Using the Command Line

You can use the ldapmodify utility to set the log level. For example, to enable search filter logging (32) and config file processing (64), set the nsslapd-errorlog-level parameter to 96 (32 + 64):
# ldapmodify -D "cn=Directory Manager" -W -x
dn: cn=config
changetype: modify
replace: nsslapd-errorlog-level
nsslapd-errorlog-level: 96

20.4. Getting Access Log Statistics

The logconv.pl script parses the access log and returns summary information on different users and operations that have been run on the server.
At its simplest, the script simply parses the access log (or logs):
# logconv.pl /relative/path/to/accessLog
The script can accept wildcards to parse multiple access logs, which is useful if log rotation is used.
# logconv.pl /var/log/dirsrv/slapd-instance/access*
The different options for logconv.pl are covered in the manpage and in the Configuration, Command, and File Reference.
There are several different ways that logconv.pl can be used to pull general usage information from the access logs.
At its simplest, logconv.pl prints a list of total operations, total number of connections, counts per each operation type, counts for some extended operations like persistent searches, and bind information.
# logconv.pl /var/log/dirsrv/slapd-instance/access
Access Log Analyzer 8.2
Command: logconv.pl /var/log/dirsrv/slapd-instance/access
Processing 1 Access Log(s)...

[001] /var/log/dirsrv/slapd-instance/access	size (bytes):        77532

Total Log Lines Analysed:  527

Start of Logs:    14/Oct/2017:16:15:22.452909568
End of Logs:      14/Oct/2017:16:39:50.157790196

Processed Log Time:  0 Hours, 24 Minutes, 27.704877056 Seconds

Restarts:                     10
Secure Protocol Versions:
  - TLS1.2 client bound as uid=user_name,ou=people,o=example.com (11 connections)
  - TLS1.2 128-bit AES; client CN=CA Subsystem,O=example.com; issuer CN=Certificate Authority,O=example.com (11 connections)
  - TLS1.2 128-bit AES-GCM (2 connections)
  - TLS1.2 128-bit AES (3 connections)

Peak Concurrent Connections:  38
Total Operations:             4771
Total Results:                4653
Overall Performance:          97.5%

Total Connections:            249           (0.17/sec)  (10.18/min)
 - LDAP Connections:          107           (0.07/sec)  (4.37/min)
 - LDAPI Connections:         128           (0.09/sec)  (5.23/min)
 - LDAPS Connections:         14            (0.01/sec)  (0.57/min)
 - StartTLS Extended Ops:     2             (0.00/sec)  (0.08/min)

Searches:                     2963          (2.02/sec)  (121.13/min)
Modifications:                649           (0.44/sec)  (26.53/min)
Adds:                         785           (0.53/sec)  (32.09/min)
Deletes:                      10            (0.01/sec)  (0.41/min)
Mod RDNs:                     6             (0.00/sec)  (0.25/min)
Compares:                     0             (0.00/sec)  (0.00/min)
Binds:                        324           (0.22/sec)  (13.25/min)

Proxied Auth Operations:      0
Persistent Searches:          17
Internal Operations:          0
Entry Operations:             0
Extended Operations:          4
Abandoned Requests:           0
Smart Referrals Received:     0

VLV Operations:               30
VLV Unindexed Searches:       0
VLV Unindexed Components:     20
SORT Operations:              22

Entire Search Base Queries:   12
Paged Searches:               2
Unindexed Searches:           0
Unindexed Components:         149

FDs Taken:                    249
FDs Returned:                 212
Highest FD Taken:             107

Broken Pipes:                 0
Connections Reset By Peer:    0
Resource Unavailable:         0
Max BER Size Exceeded:        0

Binds:                        324
Unbinds:                      155
---------------------------------
 - LDAP v2 Binds:             41
 - LDAP v3 Binds:             180
 - AUTOBINDs(LDAPI):          103
 - SSL Client Binds:          0
 - Failed SSL Client Binds:   0
 - SASL Binds:                134
   - EXTERNAL: 114
   - GSSAPI: 20
 - Directory Manager Binds:   10
 - Anonymous Binds:           1

Cleaning up temp files...
Done.
In addition to the summary information for operations and connections, more detailed summary information for all of the connections to the server. This information includes things like most common IP addresses used to connect to the server, DNs with the most failed login attempts, total bind DNs used to access the server, and the most common error or return codes.
Additional connection summaries are passed as a single option. For example, listing the number of DNs used to connect to the server (b) and the total connection codes returned by the server (c) are passed as -bc.
# logconv.pl -bc /var/log/dirsrv/slapd-instance/access
...
----- Total Connection Codes -----

U1              3    Cleanly Closed Connections
B1              1    Bad Ber Tag Encountered

----- Top 20 Bind DN's -----

Number of Unique Bind DN's: 212

1801            cn=Directory Manager
1297            Anonymous Binds
311             uid=jsmith,ou=people...
87              uid=bjensen,ou=peopl...
85              uid=mreynolds,ou=peo...
69              uid=jrockford,ou=peo...
55              uid=sspencer,ou=peop...
...
The data can be limited to entries after a certain start time (-S), before a certain end time (-E), or within a range. When start and end times are set, the logconv.pl first prints the time range given, then the summary for that period.
# logconv.pl -S "[01/Jul/2016:16:11:47.000000000 -0400]" -E "[01/Jul/2016:17:23:08.999999999 -0400]" /var/log/dirsrv/slapd-instance/access
...
----------- Access Log Output ------------

Start of Logs:    01/Jul/2016:16:11:47
End of Logs:      01/Jul/2016:17:23:08
...
The start and end period only sets time limits for the data used to generate the total summary counts. It still shows aggregated, or total, counts. To get a view of the patterns in connections and operations to the Directory Server, it is possible to output data with counts per minute (-M) or per second (-m). In this case, the data are printed, in time unit increments, to a specified CSV output file.
# logconv.pl -m|-M outputFile accessLogFile
For example:
# logconv.pl -M /home/output/statsPerMin.txt /var/log/dirsrv/slapd-instance/access*
The -M|-m options can also be used with the -S and -E arguments, to get per-minute or per-second counts within a specific time period.
Each row in the file represents one unit of time, either minute or second, with total counts for that time period. The CSV file (for both per-minute and per-second statistics) contains the following columns, in order:
Time,time_t,Results,Search,Add,Mod,Modrdn,Delete,Abandon,Connections,SSL Conns,Bind,Anon Bind,Unbind,Unindexed
The CSV file can be manipulated in any spreadsheet program, like LibreOffice Calc, and in many other business applications. The procedures for importing the CSV data and generating charts or other metrics depends on the application itself.
For example, to create a chart in LibreOffice Calc:
  1. Open the CSV file.
  2. Click the Insert menu, and select Chart.
  3. In the Chart Type area, set the chart type to XY (Scatter).
    1. Set the subtype to lines only.
    2. Select the option to sort by X values.
  4. Accept the defaults in the other screens (particularly, to use the data series in columns and to set the first row and first column as labels), and create the chart.

20.5. Monitoring the Local Disk for Graceful Shutdown

When the disk space available on a system becomes too small, the Directory Server process (slapd) crashes. Any abrupt shutdown runs the risk of corrupting the database or losing directory data.
It is possible to monitor the disk space available to the slapd process. A disk monitoring thread is enabled using the nsslapd-disk-monitoring configuration attribute. This creates a monitoring thread that wakes every ten (10) seconds to check for available disk space in certain areas.
If the disk space approaches a defined threshold, then the slapd begins a series of steps (by default) to reduce the amount of disk space it is consuming:
  • Verbose logging is disabled.
  • Access logging and error logging are disabled.
  • Rotated (archived) logs are deleted.

Note

Error log messages are always recorded, even when other changes are made to the logging configuration.
If the available disk space continues to drop to half of the configured threshold, then the slapd begins a graceful shut down process (within a grace period); and if the available disk space ever drops to 4KB, then the slapd process shuts down immediately. If the disk space is freed up, then the shutdown process is aborted, and all of the previously disabled log settings are re-enabled.
By default, the monitoring thread checks the configuration, transaction log, and database directories. An additional attribute (nsslapd-disk-monitoring-logging-critical) can be set to include the logs directory when evaluating disk space.
Disk monitoring is disabled by default, but it can be enabled and configured by adding the appropriate configuration attributes to the cn=config entry. Table 20.1, “Disk Monitoring Configuration Attributes” lists all of the configuration options.
  1. Using ldapmodify, add the disk monitoring attributes. At a minimum, turn on the nsslapd-disk-monitoring attribute to enable disk monitoring. The default threshold is 2MB; this can be configured (optionally) in the nsslapd-disk-monitoring-threshold attribute.
    For example:
    # ldapmodify -D "cn=Directory Manager" -W -x
    dn: cn=config
    changetype: modify
    add: nsslapd-disk-monitoring
    nsslapd-disk-monitoring: on
    -
    add: nsslapd-disk-monitoring-threshold
    nsslapd-disk-monitoring-threshold: 3000000
    -
    add: nsslapd-disk-monitoring-grace-period
    nsslapd-disk-monitoring-grace-period: 20
  2. Restart the Directory Server to load the new configuration.
    [root@server ~]# systemctl restart dirsrv.target

Table 20.1. Disk Monitoring Configuration Attributes

Configuration Attribute Description
nsslapd-disk-monitoring Enabled disk monitoring. This is the only required attribute, since the other configuration options have usable defaults.
nsslapd-disk-monitoring-grace-period Sets a grace period to wait before shutting down the server after it hits half of the disk space limit. This gives an administrator time to address the situation. The default value is 60 (minutes).
nsslapd-disk-monitoring-logging-critical Sets whether to shut down the server if the log directories pass the halfway point set in the disk space limit. This prevents the monitoring thread from disabling audit or access logging or from deleting rotated logfiles.
nsslapd-disk-monitoring-threshold Sets the amount of disk space, in bytes, to use to evaluate whether the server has enough available disk space. Once the space reaches half of this threshold, then the server begins a shut down process. The default value is 2000000 (2MB).

20.6. Monitoring Server Activity

The Directory Server's current activities can be monitored from either the Directory Server Console or the command line. It is also possible to monitor the activity of the caches for all of the database.

20.6.1. Monitoring the Server from the Directory Server Console

  1. Select the Status tab.
  2. In the navigation tree, select Performance Counters.
    The Status tab in the right pane displays current information about server activity. If the server is currently not running, this tab will not provide performance monitoring information.
  3. Click Refresh to refresh the current display. For the server to continuously update the displayed information, select the Continuous check box.
The General Information table shows basic information about the server, which helps set a baseline about the statistics that have been gathered.

Table 20.2. General Information (Server)

Field Description
Server Version Identifies the current server version.
Startup Time on Server The date and time the server was started.
Current Time on Server The current date and time on the server.
The Resource Summary table shows the totals of all operations performed by that instance.

Table 20.3. Resource Summary

Resource Usage Since Startup Average Per Minute
Connections The total number of connections to this server since server startup. Average number of connections per minute since server startup.
Operations Initiated The total number of operations initiated since server startup. Operations include any client requests for server action,such as searches, adds, and modifies. Often, multiple operations are initiated for each connection. Average number of operations per minute since server startup.
Operations Completed The total number of operations completed by the server since server startup. Average number of operations per minute since server startup.
Entries Sent to Clients The total number of entries sent to clients since server startup. Entries are sent to clients as the result of search requests. Average number of entries sent to clients per minute since server startup.
Bytes Sent to Clients The total number of bytes sent to clients since server startup. Average number of bytes sent to clients per minute since server startup.
The Current Resource Usage table shows the current demands on the server.

Table 20.4. Current Resource Usage

Resource Current Total
Active Threads The current number of active threads used for handling requests. Additional threads may be created by internal server tasks, such as replication or chaining.
Open Connections The total number of open connections. Each connection can account for multiple operations, and therefore multiple threads.
Remaining Available Connections The total number of remaining connections that the server can concurrently open. This number is based on the number of currently open connections and the total number of concurrent connections that the server is allowed to open. In most cases, the latter value is determined by the operating system and is expressed as the number of file descriptors available to a task.
Threads Waiting to Write to Client The total number of threads waiting to write to the client. Threads may not be immediately written when the server must pause while sending data to a client. Reasons for a pause include a slow network, a slow client, or an extremely large amount of information being sent to the client.
Threads Waiting to Read from Client The total number of threads waiting to read from the client. Threads may not be immediately read if the server starts to receive a request from the client, and then the transmission of that request is halted for some reason. Generally, threads waiting to read are an indication of a slow network or client.
Databases in Use The total number of databases being serviced by the server.
The Connection Status table simply lists the current active connections, with related connection information.

Table 20.5. Connection Status

Table Header Description
Time Opened The time on the server when the connection was initially opened.
Started The number of operations initiated by this connection.
Completed The number of operations completed by the server for this connection.
Bound as The distinguished name used by the client to bind to the server. If the client has not authenticated to the server, the server displays not bound in this field.
Read/Write Indicates whether the server is currently blocked for read or write access to the client. There are two possible values:
Not blocked means that the server is idle,actively sending data to the client, or actively reading data from the client.
Blocked means that the server is trying to send data to the client or read data from the client but cannot. The probable cause is a slow network or client.
The Global Database Cache table lists the cache information for all databases within the Directory Server instance.

Note

Although the performance counter for the global database cache is listed with the other server performance counters in the Directory Server Console, the actual database cache entries are located and monitored in cn=monitor,cn=database_instance,cn=ldbm database,cn=plugins,cn=config, as are the other database activities. Monitoring these entries through the command line is covered in Section 20.7.2, “Monitoring Databases from the Command Line”.

Table 20.6. Global Database Cache Information

Table Header Description
Hits The number of times the server could process a request by obtaining data from the cache rather than by going to the disk.
Tries The total number of database accesses since server startup.
Hit Ratio The ratio of cache tries to successful cache hits. The closer this number is to 100%, the better.
Pages Read In The number of pages read from disk into the cache.
Pages Written Out The number of pages written from the cache back to disk.
Read-Only Page Evicts The number of read-only pages discarded from the cache to make room for new pages. Pages discarded from the cache have to be written to disk, possibly affecting server performance. The lower the number of page evicts the better.
Read-Write Page Evicts The number of read-write pages discarded from the cache to make room for new pages. This value differs from Pages Written Out in that these are discarded read-write pages that have not been modified. Pages discarded from the cache have to be written to disk, possibly affecting server performance. The lower the number of page evicts, the better.

20.6.2. Monitoring the Directory Server from the Command Line

The Directory Server's current activities can be monitored using LDAP tools such as ldapsearch, with the following characteristics:
  • Search with the attribute filter objectClass=*.
  • Use the search base cn=monitor; the monitoring attributes for the server are found in the cn=monitor entry.
  • Use the search scope base.
For example:
# ldapsearch -D "cn=Directory Manager" -W -p 389 -h server.example.com -x -s base -b "cn=monitor" "(objectclass=*)"
The monitoring attributes for the Directory Server are found in the cn=monitor entry. For information on searching the Directory Server, see Section 14.3, “Using ldapsearch”.

Table 20.7. Server Monitoring Attributes

Attribute Description
version Identifies the directory's current version number.
threads The current number of active threads used for handling requests. Additional threads may be created by internal server tasks, such as replication or chaining.
connection:fd:opentime:opsinitiated:opscompleted:binddn:[rw] Provides the following summary information for each open connection (only available if you bind to the directory as Directory Manager):
fd — The file descriptor used for this connection.
opentime — The time this connection was opened.
opsinitiated — The number of operations initiated by this connection.
opscompleted — The number of operations completed.
binddn — The distinguished name used by this connection to connect to the directory.
rw — The field shown if the connection is blocked for read or write.
By default, this information is available to Directory Manager. However, the ACI associated with this information can be edited to allow others to access the information.
currentconnections Identifies the number of connections currently in service by the directory.
totalconnections Identifies the number of connections handled by the directory since it started.
dtablesize Shows the number of file descriptors available to the directory. Each connection requires one file descriptor: one for every open index, one for log file management, and one for ns-slapd itself. Essentially, this value shows how many additional concurrent connections can be serviced by the directory. For more information on file descriptors, see the operating system documentation.
readwaiters Identifies the number of threads waiting to read data from a client.
opsinitiated Identifies the number of operations the server has initiated since it started.
opscompleted Identifies the number of operations the server has completed since it started.
entriessent Identifies the number of entries sent to clients since the server started.
bytessent Identifies the number of bytes sent to clients since the server started.
currenttime Identifies the time when this snapshot of the server was taken. The time is displayed in Greenwich Mean Time (GMT) in UTC format.
starttime Identifies the time when the server started. The time is displayed in Greenwich Mean Time (GMT) in UTC format.
nbackends Identifies the number of back ends (databases) the server services.
backendmonitordn Identifies the DN of each directory database.

20.7. Monitoring Database Activity

The database's current activities can be monitored through Directory Server Console or from the command line.

Note

Tips for tuning the entry and database caches to improve server performance are in the Red Hat Directory Server Performance Tuning Guide.

20.7.1. Monitoring Database Activity from the Directory Server Console

To monitor the database's activities:
  1. In the Directory Server Console, select the Status tab.
  2. In the navigation tree, expand the Performance Counters folder, and select the database to monitor.
    The tab displays current information about database activity. If the server is currently not running, this tab will not provide performance monitoring information.
  3. Click Refresh to refresh the currently displayed information. For the directory to continuously update the displayed information, select the Continuous check box, and then click Refresh.

Table 20.8. General Information (Database)

Field Description
Database Identifies the type of database being monitored.
Configuration DN Identifies the distinguished name that must be used as a search base to obtain these results using the ldapsearch command-line utility.
The Summary Information section shows the cumulative information for all of the databases being monitored and some cache-related configuration settings which are applied to all databases.

Table 20.9. Summary Information

Performance Metric Current Total
Read-Only Status Shows whether the database is currently in read-only mode. The database is in read-only mode when the nsslapd-readonly attribute is set to on.
Entry Cache Hits The total number of successful entry cache lookups. That is, the total number of times the server could process a search request by obtaining data from the cache rather than by going to disk.
Entry Cache Tries The total number of entry cache lookups since the directory was last started. That is, the total number of entries requested since server startup.
Entry Cache Hit Ratio
Ratio that indicates the number of entry cache tries to successful entry cache lookups. This number is based on the total lookups and hits since the directory was last started. The closer this value is to 100%, the better. Whenever an operation attempts to find an entry that is not present in the entry cache, the directory has to perform a disk access to obtain the entry. Thus, as this ratio drops towards zero, the number of disk accesses increases, and directory search performance drops.
To improve the ratio, enable the entry cache auto-tuning. For details, see the corresponding section in the Red Hat Directory Server Performance Tuning Guide.
Current Entry Cache Size (in Bytes) The total size of directory entries currently present in the entry cache.
Maximum Entry Cache Size (in Bytes)
The size of the entry cache maintained by the directory.
The size of the entry cache is set in the nsslapd-cachememsize attribute in the cn=database_name,cn=ldbm database,cn=plugins,cn=config entry. For optimized performance, enable entry cache auto-tuning. For details, see the corresponding section in the Red Hat Directory Server Performance Tuning Guide.
Current Entry Cache Size (in Entries) The number of directory entries currently present in the entry cache.
Maximum Entry Cache Size (in Entries)
DEPRECATED.
The maximum number of directory entries that can be maintained in the entry cache.
Do not attempt to manage the cache size by setting a maximum number of allowed entries. This can make it difficult for the host to allocate RAM effectively.
There are many different databases listed for the database monitoring page, by default, because databases are maintained for both entries and indexed attributes. All databases, though, have the same kind of cache information monitored in the counters.

Table 20.10. Database Cache Information

Performance Metric Current Total
Hits The number of times the database cache successfully supplied a requested page.
Tries The number of times the database cache was asked for a page.
Hit Ratio
The ratio of database cache hits to database cache tries. The closer this value is to 100%, the better. Whenever a directory operation attempts to find a portion of the database that is not present in the database cache, the directory has to perform a disk access to obtain the appropriate database page. Thus, as this ratio drops towards zero, the number of disk accesses increases, and directory performance drops.
To improve the ratio, enable the database cache auto-tuning. For details, see the corresponding section in the Red Hat Directory Server Performance Tuning Guide.
Pages Read In The number of pages read from disk into the database cache.
Pages Written Out The number of pages written from the cache back to disk. A database page is written to disk whenever a read-write page has been modified and then subsequently deleted from the cache. Pages are deleted from the database cache when the cache is full and a directory operation requires a database page that is not currently stored in cache.
Read-Only Page Evicts The number of read-only pages discarded from the cache to make room for new pages.
Read-Write Page Evicts The number of read-write pages discarded from the cache to make room for new pages. This value differs from Pages Written Out in that these are discarded read-write pages that have not been modified.

Table 20.11. Database File-Specific

Performance Metric Current Total
Cache Hits The number of times that a search result resulted in a cache hit on this specific file. That is, a client performs a search that requires data from this file, and the directory obtains the required data from the cache.
Cache Misses The number of times that a search result failed to hit the cache on this specific file. That is, a search that required data from this file was performed, and the required data could not be found in the cache.
Pages Read In The number of pages brought to the cache from this file.
Pages Written Out The number of pages for this file written from cache to disk.

20.7.2. Monitoring Databases from the Command Line

A database's current activities can be monitored using LDAP tools such as ldapsearch. The search targets the monitoring subtree of the LDBM database entry, cn=monitor,cn=database_name,cn=ldbm database,cn=plugins,cn=config. This contains all of the monitoring attributes for the that specific database instance.
For example:
# ldapsearch -D "cn=Directory Manager" -W -p 389 -h server.example.com -x -s base -b "cn=monitor,cn=database_name,cn=ldbm database,cn=plugins,cn=config" "(objectclass=*)"

Table 20.12. Database Monitoring Attributes

Attribute Description
database Identifies the type of database currently being monitored.
readonly Indicates whether the database is in read-only mode; 0 means that the server is not in read-only mode, 1 means that it is in read-only mode.
entrycachehits The total number of successful entry cache lookups. That is, the total number of times the server could process a search request by obtaining data from the cache rather than by going to disk.
entrycachetries The total number of entry cache lookups since the directory was last started. That is, the total number of search operations performed against the server since server startup.
entrycachehitratio
Ratio that indicates the number of entry cache tries to successful entry cache lookups. This number is based on the total lookups and hits since the directory was last started. The closer this value is to 100%, the better. Whenever a search operation attempts to find an entry that is not present in the entry cache, the directory has to perform a disk access to obtain the entry. Thus, as this ratio drops towards zero, the number of disk accesses increases, and directory search performance drops.
To improve the ratio, enable the entry cache auto-tuning. For details, see the corresponding section in the Red Hat Directory Server Performance Tuning Guide.
currententrycachesize
The total size, in bytes, of directory entries currently present in the entry cache.
maxentrycachesize
The maximum size, in bytes, of directory entries that can be maintained in the entry cache.
The size of the entry cache is set in the nsslapd-cachememsize attribute in the cn=database_name,cn=ldbm database,cn=plugins,cn=config entry. For optimized performance, enable entry cache auto-tuning. For details, see the corresponding section in the Red Hat Directory Server Performance Tuning Guide.
dbcachehits The number of times the server could process a request by obtaining data from the cache rather than by going to the disk.
dbcachetries The total number of database accesses since server startup.
dbcachehitratio The ratio of cache tries to successful cache hits. The closer this number is to 100%, the better.
dbcachepagein The number of pages read from disk into the cache.
dbcachepageout The number of pages written from the cache back to disk.
dbcacheroevict The number of read-only pages discarded from the cache to make room for new pages. Pages discarded from the cache have to be written to disk, possibly affecting server performance. The lower the number of page evicts the better.
dbcacherwevict The number of read-write pages discarded from the cache to make room for new pages. This value differs from Pages Written Out in that these are discarded read-write pages that have not been modified. Pages discarded from the cache have to be written to disk, possibly affecting server performance. The lower the number of page evicts the better.
dbfilename-number The name of the file. number provides a sequential integer identifier (starting at 0) for the file. All associated statistics for the file are given this same numerical identifier.
dbfilecachehit-number The number of times that a search result resulted in a cache hit on this specific file. That is, a client performs a search that requires data from this file, and the directory obtains the required data from the cache.
dbfilecachemiss-number The number of times that a search result failed to hit the cache on this specific file. That is, a search that required data from this file was performed, and the required data could not be found in the cache.
dbfilepagein-number The number of pages brought to the cache from this file.
dbfilepageout-number The number of pages for this file written from cache to disk.
currentdncachesize
The total size, in bytes, of DNs currently present in the DN cache.
To increase the size of the entries which can be present in the DN cache, increase the value of the nsslapd-dncachememsize attribute in the cn=database_name, cn=ldbm database,cn=plugins,cn=config entry for the database.
maxdncachesize
The maximum size, in bytes, of DNs that can be maintained in the DN cache.
To increase the size of the entries which can be present in the cache, increase the value of the nsslapd-dncachememsize attribute in the cn=database_name, cn=ldbm database,cn=plugins,cn=config entry for the database.
currentdncachecount The number of DNs currently present in the DN cache.

20.9. Enabling and Disabling Counters

The nsslapd-counters attribute enabled counters to run. However, running counters can affect performance, so it also possible to turn off counters. If counters are off, they all have a value of zero (0).
By default, counters are already enabled. To enable or disable performance counters, use ldapmodify:
ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x

dn: cn=config
changetype: modify
replace: nsslapd-counters
nsslapd-counters: off

Chapter 21. Monitoring Directory Server Using SNMP

The server and database activity monitoring log setup described in Chapter 20, Monitoring Server and Database Activity is specific to Directory Server. You can also monitor your Directory Server using Simple Network Management Protocol (SNMP), which is a management protocol used for monitoring network activity which can be used to monitor a wide range of devices in real time.
Directory Server can be monitored with SNMP through an AgentX subagent. SNMP monitoring collects useful information about the Directory Server, such as bind information, operations performed on the server, and cache information. The Directory Server SNMP subagent supports SNMP traps to send notifications about changes in the running state of your server instances.

21.1. About SNMP

SNMP has become interoperable on account of its widespread popularity. It is this interoperability, combined with the fact that SNMP can take on numerous jobs specific to a whole range of different device classes, that make SNMP the ideal standard mechanism for global network control and monitoring. SNMP allows network administrators to unify all network monitoring activities, with Directory Server monitoring part of the broader picture.
SNMP is used to exchange data about network activity. With SNMP, data travels between a managed device and a network management application (NMS) where users remotely manage the network. A managed device is anything that runs SNMP, such as hosts, routers, and your Directory Server. An NMS is usually a powerful workstation with one or more network management applications installed. A network management application graphically shows information about managed devices, which device is up or down, which and how many error messages were received, and so on.
Information is transferred between the NMS and the managed device through the use of two types of agents: the subagent and the master agent. The subagent gathers information about the managed device and passes the information to the master agent. Directory Server has a subagent. The master agent exchanges information between the various subagents and the NMS. The master agent usually runs on the same host machine as the subagents it talks to, although it can run on a remote machine.
Values for SNMP attributes, otherwise known as variables, that can be queried are kept on the managed device and reported to the NMS as necessary. Each variable is known as a managed object, which is anything the agent can access and send to the NMS. All managed objects are defined in a management information base (MIB), which is a database with a tree-like hierarchy. The top level of the hierarchy contains the most general information about the network. Each branch underneath is more specific and deals with separate network areas.
SNMP exchanges network information in the form of protocol data units (PDUs). PDUs contain information about variables stored on the managed device. These variables, also known as managed objects, have values and titles that are reported to the NMS as necessary. Communication between an NMS and a managed device takes place either by the NMS sending updates or requesting information or by the managed object sending a notice or warning, called a trap, when a server shuts down or starts up.

21.2. Configuring the Directory Server for SNMP

By default, the Directory Server is ready to be monitored using SNMP as soon as the subagent is configured. However, there are some useful variables in the Directory Server instances which can be configured to help identify the Directory Server instance with SNMP. To configure these SNMP settings from the Directory Server Console:
  1. Select the Configuration tab, and then select the topmost entry in the navigation tree in the left pane.
  2. Select the SNMP tab in the main window.
  3. Fill in the information about the SNMP descriptors so that it is easy to identify the Directory Server instance in Net-SNMP.
    • A unique name and description for the instance.
    • The company or organization to which the directory instance belongs.
    • The physical location of the directory instance or the organization which manages the instance.
    • The email address or contact number for the person who maintains the Directory Server instance.
  4. Click Save.

21.3. Setting up an SNMP Agent for Directory Server

To query information from Directory Server using the SNMP protocol, set up an SNMP agent:
  1. Install the 389-ds-base-snmp and net-snmp packages:
    # yum install 389-ds-base-snmp net-snmp
  2. To configure the SNMP master agent, edit the /etc/snmp/snmpd.conf file, adding the following entry to enable the agent extensibility (AgentX) protocol:
    master agentx
    For further details about the AgentX protocol, see RFC 2741.
  3. To configure the SNMP subagent, edit the /etc/dirsrv/config/ldap-agent.conf file, adding a server parameter for each Directory Server instance you want to monitor. For example:
    server slapd-instance_name
  4. Optionally, create an SNMP user account:
    1. Stop the snmpd service:
      # systemctl stop snmpd
    2. Create the SNMP user account. For example:
      # net-snmp-create-v3-user -A authentication_password -a SHA \
           -X private_password -x AES user_name
      For details about the parameters used in the command, see the net-snmp-create-v3-user(1) man page.
    3. Start the snmpd service:
      # systemctl start snmpd
  5. Optionally, set the Directory Server descriptive properties. For details, see Section 21.2, “Configuring the Directory Server for SNMP”.
  6. Start the dirsrv-snmp service:
    # systemctl start dirsrv-snmp
  7. Optionally, to verify the configuration:
    1. Install the net-snmp-utils package:
      # yum install net-snmp-utils
    2. Query the Directory Server Object Identifiers (OID). For example:
      # snmpwalk -v3 -u user_name -M /usr/share/snmp/mibs:/usr/share/dirsrv/mibs/ \
           -l AuthPriv -m +RHDS-MIB -A authentication_password -a SHA
           -X private_password -x AES server.example.com .1.3.6.1.4.1.2312.6.1.1
For further details about SNMP, see the Monitoring Performance with Net-SNMP section in the Red Hat System Administrator's Guide.

21.4. Configuring SNMP Traps

An SNMP trap is essentially a threshold which triggers a notification if it is encountered by the monitored server. To use traps, the master agent must be configured to accept traps and do something with them. For example, a trap can trigger an email notification for an administrator of the Directory Server instance stops.
The subagent is only responsible for sending the traps to the master agent. The master agent and a trap handler must be configured according to the documentation for the SNMP master agent you are using.
Traps are accompanied by information from the Entity Table, which contains information specific to the Directory Server instance, such as its name and version number. The Entity Table is described in Section 21.5.3, “Entity Table”. This means that the action the master agent takes when it receives a trap is flexible, such as sending an email to an email address defined in the dsEntityContact variable for one instance while sending a notification to a pager number in the dsEntityContact variable for another instance.
There are two traps supported by the subagent:
  • DirectoryServerDown. This trap is generated whenever the subagent detects the Directory Server is potentially not running. This trap will be sent with the Directory Server instance description, version, physical location, and contact information, which are detailed in the dsEntityDescr, dsEntityVers, dsEntityLocation, and dsEntityContact variables.
  • DirectoryServerStart. This trap is generated whenever the subagent detects that the Directory Server has started or restarted. This trap will be sent with the Directory Server instance description, version, physical location, and contact information, which are detailed in the dsEntityDescr, dsEntityVers, dsEntityLocation, and dsEntityContact variables.

21.5. Using the Management Information Base

The Directory Server's MIB is a file called redhat-directory.mib. This MIB contains definitions for variables pertaining to network management for the directory. These variables are known as managed objects. Using the directory MIB and Net-SNMP, you can monitor your directory like all other managed devices on your network. For more information on using the MIB, see Section 21.3, “Setting up an SNMP Agent for Directory Server”.
The client tools need to load the Directory Server MIB to use the variable names listed in the following sections.
Using the directory MIB enables administrators to use SNMP to see administrative information about the directory and monitor the server in real-time. The directory MIB is broken into four distinct tables of managed objects:

Note

All of the Directory Server attributes monitored by SNMP use 64-bit integers for the counters, even on 32-bit systems.

21.5.1. Operations Table

The Operations Table provides statistical information about Directory Server access, operations, and errors. Table 21.1, “Operations Table: Managed Objects and Descriptions” describes the managed objects stored in the Operations Table of the redhat-directory.mib file.

Table 21.1. Operations Table: Managed Objects and Descriptions

Managed Object Description
dsAnonymousBinds The number of anonymous binds to the directory since server startup.
dsUnauthBinds The number of unauthenticated binds to the directory since server startup.
dsSimpleAuthBinds The number of binds to the directory that were established using a simple authentication method (such as password protection) since server startup.
dsStrongAuthBinds The number of binds to the directory that were established using a strong authentication method (such as TLS or a SASL mechanism like Kerberos) since server startup.
dsBindSecurityErrors The number of bind requests that have been rejected by the directory due to authentication failures or invalid credentials since server startup.
dsInOps The number of operations forwarded to this directory from another directory since server startup.
dsReadOps The number of read operations serviced by this directory since application start. The value of this object will always be 0 because LDAP implements read operations indirectly using the search operation.
dsCompareOps The number of compare operations serviced by this directory since server startup.
dsAddEntryOps The number of add operations serviced by this directory since server startup.
dsRemoveEntryOps The number of delete operations serviced by this directory since server startup.
dsModifyEntryOps The number of modify operations serviced by this directory since server startup.
dsModifyRDNOps The number of modify RDN operations serviced by this directory since server startup.
dsListOps The number of list operations serviced by this directory since server startup. The value of this object will always be 0 because LDAP implements list operations indirectly using the search operation.
dsSearchOps The total number of search operations serviced by this directory since server startup.
dsOneLevelSearchOps The number of one-level search operations serviced by this directory since server startup.
dsWholeSubtreeSearchOps The number of whole subtree search operations serviced by this directory since server startup.
dsReferrals The number of referrals returned by this directory in response to client requests since server startup.
dsSecurityErrors The number of operations forwarded to this directory that did not meet security requirements.
dsErrors The number of requests that could not be serviced due to errors (other than security or referral errors). Errors include name errors, update errors, attribute errors, and service errors. Partially serviced requests will not be counted as an error.

21.5.2. Entries Table

The Entries Table provides information about the contents of the directory entries. Table 21.2, “Entries Table: Managed Objects and Descriptions” describes the managed objects stored in the Entries Table in the redhat-directory.mib file.

Table 21.2. Entries Table: Managed Objects and Descriptions

Managed Object Description
dsMasterEntries The number of directory entries for which this directory contains the master entry. The value of this object will always be 0 (as no updates are currently performed).
dsCopyEntries The number of directory entries for which this directory contains a copy.The value of this object will always be 0 (as no updates are currently performed).
dsCacheEntries The number of entries cached in the directory.
dsCacheHits The number of operations serviced from the locally held cache since application startup.
dsSlaveHits The number of operations that were serviced from locally held replications (shadow entries). The value of this object will always be 0.

21.5.3. Entity Table

The Entity Table contains identifying information about the Directory Server instance. The values for the Entity Table are set in the Directory Server Console, as described in Section 21.2, “Configuring the Directory Server for SNMP”.
Table 21.3, “Entity Table: Managed Objects and Descriptions” describes the managed objects stored in the Entity Table of the redhat-directory.mib file.

Table 21.3. Entity Table: Managed Objects and Descriptions

Managed Object Description
dsEntityDescr The description set for the Directory Server instance.
dsEntityVers The Directory Server version number of the Directory Server instance.
dsEntityOrg The organization responsible for the Directory Server instance.
dsEntityLocation The physical location of the Directory Server instance.
dsEntityContact The name and contact information for the person responsible for the Directory Server instance.
dsEntityName The name of the Directory Server instance.

21.5.4. Interaction Table

Note

The Interaction Table is not supported by the subagent. The subagent can query the table, but it will not ever be updated with valid data.
Table 21.4, “Interaction Table: Managed Objects and Descriptions” describes the managed objects stored in the Interaction Table of the redhat-directory.mib file.

Table 21.4. Interaction Table: Managed Objects and Descriptions

Managed Object Description
dsIntTable Details, in each row of the table, related to the history of the interaction of the monitored Directory Servers with their respective peer Directory Servers.
dsIntEntry The entry containing interaction details of a Directory Server with a peer Directory Server.
dsIntIndex Part of the unique key, together with applIndex, to identify the conceptual row which contains useful information on the (attempted) interaction between the Directory Server (referred to by applIndex) and a peer Directory Server.
dsName The distinguished name (DN) of the peer Directory Server to which this entry belongs.
dsTimeOfCreation The value of sysUpTime when this row was created. If the entry was created before the network management subsystem was initialized, this object will contain a value of zero.
dsTimeOfLastAttempt The value of sysUpTime when the last attempt was made to contact this Directory Server. If the last attempt was made before the network management subsystem was initialized, this object will contain a value of zero.
dsTimeOfLastSuccess The value of sysUpTime when the last attempt made to contact this Directory Server was successful. This entry will have a value of zero if there have been no successful attempts or if the last successful attempt was made before the network management subsystem was initialized.
dsFailuresSinceLastSuccess The number of failures since the last time an attempt to contact this Directory Server was successful. If there has been no successful attempts, this counter will contain the number of failures since this entry was created.
dsFailures Cumulative failures since the creation of this entry.
dsSuccesses Cumulative successes since the creation of this entry.
dsURL The URL of the Directory Server application.

Chapter 22. Making a High-availability and Disaster Recovery Plan

Part of running a Directory Server deployment efficiently is planning for that worst case scenario. This chapter covers general principles for drafting a disaster recovery plan and highlights features in Directory Server that can be used to aide in disaster recovery.
Disaster recovery is a way of planning and implementing a smooth transition from one operating environment to another environment whenever there is some sort of catastrophic failure. A disaster recovery plan for Directory Server may be part of a larger business continuity plan or it could be a standalone plan specifically for an interruption in directory services.

Note

This chapter covers very general concepts for disaster recovery.
Disaster recovery can be a very complex and detail-specific thing. Consider using a professional service to design, maintain, and test any disaster recovery plan for sensitive or mission-critical services, like Red Hat Directory Server.

22.1. Identifying Potential Scenarios

The first step is identifying what potential issues you may encounter, what services will be affected, and what responses you should take. In the Red Hat Directory Server Deployment Guide, administrators made a site survey of their existing and proposed infrastructure to determine what kind of directory to design. Do something similar for disaster planning; as in Table 22.1, “Disaster Scenarios and Responses”, identify where your data infrastructure is, determine what the affect of losing that component is, and look at potential ideal responses.

Table 22.1. Disaster Scenarios and Responses

Scenario Effects on Infrastructure Ideal Response
Data corruption Through software or hardware failure (or through a malicious attack), the data at one site or on one server could be corrupted. If that corrupted server is a supplier in multi-master replication, then the corruption can quickly be propagated throughout the deployment. An isolated server should be available with access to the most recent backup of uncorrupted data. When a problem is detected, replication can be suspended on the regular infrastructure, and this server can be brought online to reinitialize the suppliers with good data.
Natural disasters and other mass events Natural disasters can take an entire office or data center offline, even through something as simple as a long-term power outage. Directory operations can be transferred to a mirrored site at another physical location, with the same data.
Server or machine loss A single machine could fail. Another machine, with the same data, can assume the lost machine's place.

22.2. Defining the Type of Rollover

Disaster recovery, as the introduction says, is the process for transitioning from one system to another system with as little interruption of service as possible. That's called a rollover, and there are three different ways of doing a rollover:
  • A hot rollover means that the infrastructure is completely mirrored at another site and that the backup site is always up and current with the primary site. This requires only a few adjustments to switch operations from the primary to the backup.
  • A warm rollover means that all of the elements for the backup site are in place (adequate network connections, all required applications and hardware) but the system is not actively running or necessarily configured. This can require some extra time to configure the machines and get the system running.
  • A cold rollover means that a site is available but there are few resources immediately available to set it up.
The obvious difference in the types of rollover is the time and expense necessary to set up the backup site. Hot and warm sites have higher initial expenditures to set up and run.
A mix of rollover types can be used, depending on the specific disaster scenario being planned. For example, a rollover plan for the loss of a single server could use a hot rollover easily and relatively cheaply by creating and keeping a virtual machine copy of the Directory Server instance which can be brought online within minutes. It would not even require keeping the virtual machine in a separate facility or network. On the other hand, a cold rollover could be planned for the loss of an entire data center or office.
Match the rollover process to the severity of the disaster scenario, your budget and available resources, and the likelihood of encountering problems.

22.3. Identifying Useful Directory Server Features for Disaster Recovery

The hardest part of a recovery is not the hardware; it is getting a reliable copy of the data in the server. There are three Directory Server features that are excellent tools for preparing data copies for disaster recovery:
  • Backing up databases and verifying the backups regularly
  • Multi-master replication, chaining, backing up databases, and monitoring the server with a named pipe script
  • Chaining
Additionally, monitoring the server with a named pipe script and with other Directory Server performance counters can be effective at catching and quickly responding to specific, critical events.

22.3.1. Backing up Directory Data for Disaster Recovery

The most useful tool for disaster recovery is to do frequent backups of a directory instance. Archives can be stored on physical media, at different locations than the primary data center or on-site at a cold backup location. Because both backup and restore operations can be done through either shell or perl scripts (such as db2bak.pl)
Backups can be automated to run regularly through cron jobs. For example:
0 7 * * 1 /usr/sbin/db2bak.pl -Z instance_name
The db2bak.pl Perl script backs up the directory data without having to stop the server first.

Note

Red Hat recommends to back up the data on all servers in a multi-master replication environment.
Backing up both directory databases and the directory configuration (dse.ldif file) are covered in Section 6.3, “Backing up and Restoring Data”.

22.3.2. Multi-Master Replication for High-availability

Multi-master replication is the best defense against losing a single server and, possibly, even an entire office or department. While a small number of servers are data masters, multiple servers all hold the same data — potentially dozens of masters and hubs in a single replication environment. This keeps information accessible to clients even if multiple servers go offline.
Replication can be used to copy over data to servers and bring replacements online more quickly.

Note

To protect against data corruption being propagated through replication, frequently back up the database.
Replication configuration also allows write operations to be referred to failover servers if the primary supplier is inaccessible. This means that write operations can proceed as normal from the client perspective, even when servers go offline.

Example 22.1. Scenarios for Multi-Master Replication

Replication is a versatile tool for disaster recovery in several scenarios:
  • For a single server failure, all of the data stored on that instance is both accessible and retrievable from other servers.
  • For the loss of an entire office or colocation facility, servers can be mirrored at an entirely different physical location (which is aided by Directory Server's wide area replication performance). With minimal effort, traffic can be redirected to the replicated site without having to bring new servers online.
Configuring replication is covered in Chapter 15, Managing Replication.

22.3.3. Chaining Databases for High-availability

Chaining is a configuration where a client sends a request to one server and it automatically forwards that request to another server to process. There can be multiple servers configured in the database link (or chain) to allow for automatic failover if one server is not available.

Example 22.2. Scenarios for Chaining

When chaining is combined with a list of failover servers, client traffic can be automatically redirected from a single server (or even group of servers) when they are offline. This does not help in recovery, but it helps manage the transition from primary to backup servers.

22.4. Defining the Recovery Process

There are a lot of tools that can help with disaster recovery, but an effective recovery process circles back to having a well-defined plan of what to do in every scenario. Two things, at least, need to be clearly identified:
  • What signals a disaster? Some things are obvious (a massive power outage, network loss, or fire), but other situations need to be defined. For example, what signals that a backup server needs to be brought online?
  • Who responds to a disaster and how? Once a disaster situation occurs, who has the responsibility to act? How are they notified of the event? What are they expected to do?

Important

  • Store a printed copy off the disaster recovery plan off-site.
  • Test the disaster recovery plan on a regular basis and after configuration and infrastructure changes.

22.5. Basic Example: Performing a Recovery

An administrator, John Smith, has to create a disaster recovery plan for his directory deployment. Example Corp. has three physical offices, in San Francisco, Dallas, and Arlington. Each site has 10 servers which replicate to each other locally, and then one server at each site replicates to another server at the other two sites.
Each site has business-critical customer data stored in its directory, as well as human resources data. Several external applications require access to the data to perform operations like billing.
John Smith's first step is to perform a site survey. He is looking for three things: what his directory usage is (clients that access it and traffic loads across the sites), what his current assets are, and what assets he may need to acquire. This is much like the initial site survey he performed when deploying Red Hat Directory Server.
His next step is identifying potential disaster scenarios. Two of the three sites are highly vulnerable to natural disasters (San Francisco and Dallas). All three sites could face normal interruptions, like outages for power or Internet access. Additionally, since each site masters its own local data, each site is vulnerable to losing a server instance or machine.
John Smith then breaks his disaster recovery plan into three parts:
  • Plan A covers losing a single instance of Directory Server
  • Plan B covers some kind of data corruption or attack
  • Plan C covers losing an entire office
For plans A and B, John Smith decides to use a hot recovery to immediately switch functionality from a single instance to the backup. Each server is backed up daily, using a cron job, and then the archive is copied over and restored on a virtual machine. The virtual machine is kept on a different subnet, but can be switched over immediately if its peer ever does offline. John Smith uses simple SNMP traps to track each Directory Server instance's availability.
Plan C is more extensive. Along with replication between sites and the local backups, he decides to mail a physical copy of each site's backup, for every local instance, once a week to the other two colocation facilities. He also keep a spare server with adequate Internet access and software licenses to restore an entire site, using virtual machines, one of the other different colocation facilities. He designates the Arlington site as the primary recovery location because that is where most of the IT staff is located, then San Francisco and last Dallas, based on the distribution of personnel. For every event, the IT administrator at all three sites will be notified, and the manager assumes the responsibilities of setting up the virtual machines, restoring the Directory Server instances from the physical backups, and rerouting client traffic.
John Smith schedules to review and update the plan quarterly to account for any new hardware or application changes. Once a year, all three sites have to run through the procedure of recovering and deploying the other two sites, according to the procedures in Disaster Plan C.

Appendix A. Using LDAP Client Tools

Red Hat Directory Server uses the LDAP tools (such as ldapsearch and ldapmodify) supplied with OpenLDAP. The OpenLDAP tool options are described in the OpenLDAP man pages at http://www.openldap.org/software/man.cgi.
This appendix gives some common usage scenarios and examples for using these LDAP tools.
More extensive examples for using ldapsearch are given in Chapter 14, Finding Directory Entries. More examples for using ldapmodify and ldapdelete are given in Section 3.1, “Managing Entries Using the Command Line”.

A.1. Running Extended Operations

Red Hat Directory Server supports a variety of extended operations, especially extended search operations. An extended operation passes an additional operation (such as a get effective rights search or server-side sort) along with the LDAP operation. Likewise, LDAP clients have the potential to support a number of extended operations.
The OpenLDAP LDAP tools support extended operations in two ways. All client tools (ldapmodify, ldapsearch, and the others) use either the -e or -E options to send an extended operation. The -e argument can be used with any OpenLDAP client tool and sends general instructions about the operation, like how to handle password policies. The -E is used only with ldapsearches and passes more useful controls like GER searches, sort and page information, and information for other, not-explicitly-support extended operations.
Additionally, OpenLDAP has another tool, ldapexop, which is used exclusively to perform extended search operations, the same as running ldapsearch -E.
The format of an extended operation with ldapsearch is generally:
-E extended_operation_type=operation_parameters
When an extended operation is explicitly handled by the OpenLDAP tools, then the extended_operation_type can be an alias, like deref for a dereference search or sss for server-side sorting. A supported extended operation has formatted output. Other extended operations, like GER searches, are passed using their OID rather than an alias, and then the extended_operation_type is the OID. For those unsupported operations the tool does not recognize the response from the server, so the output is unformatted.
For example, the pg extended operation type formats the results in simple pages:
# ldapsearch -x -D "cn=Directory Manager" -W -b "ou=Engineers,ou=People,dc=example,dc=com" -E pg=3 "(objectclass=*)" cn

dn: uid=jsmith,ou=Engineers,ou=People,dc=example,dc=com
   cn: John Smith

dn: uid=bjensen,ou=Engineers,ou=People,dc=example,dc=com
   cn: Barbara Jensen

dn: uid=hmartin,ou=Engineers,ou=People,dc=example,dc=com
   cn: Henry Martin

Results are sorted.
next page size (3): 5
The same operation with ldapexop can be run using only the OID of the simple paged results operation and the operation's settings (3 results per page):
ldapexop 1.2.840.113556.1.4.319=3
However, ldapexop does not accept the same range of search parameters that ldapsearch does, making it less flexible.

A.2. Comparing Entries

ldapcompare checks entries to see if the specified entry or entries contain an attribute of a specific value. For example, this checks to see if an entry has an sn value of Smith:
# ldapcompare -D "cn=Directory Manager" -W -p 389 -h server.example.com -x sn:smith uid=bjensen,ou=people,dc=example,dc=com
comparing type: "sn" value: "smith" in entry "uid=bjensen,ou=people,dc=example,dc=com"
compare FALSE

ldapcompare -D "cn=Directory Manager" -W -p 389 -h server.example.com -x sn:smith uid=jsmith,ou=people,dc=example,dc=com
comparing type: "sn" value: "smith" in entry "uid=jsmith,ou=people,dc=example,dc=com"
compare TRUE
The compare attribute can be specified in one of three ways:
  • A single attribute:value statement passed in the command line directly
    sn:Smith
  • A single attribute::base64value statement passed in the command line directly, for attributes like jpegPhoto or to verify certificates or CRLs
    jpegPhoto:dkdkPDKCDdko0eiofk==
  • An attribute:file statement that points to a file containing a list of comparison values for the attribute, and the script iterates through the list
    postalCode:/tmp/codes.txt
The compare operation itself has to be run against a specific entry or group of entries. A single entry DN can be passed through the command line, or a list of DNs to be compared can be given using the -f option.

Example A.1. Comparing One Attribute Value to One Entry

Both the attribute-value comparison and the DN are passed with the script.
ldapcompare -D "cn=Directory Manager" -W -p 389 -h server.example.com -x sn:smith uid=jsmith,ou=people,dc=example,dc=com
comparing type: "sn" value: "smith" in entry "uid=jsmith,ou=people,dc=example,dc=com"
compare TRUE

Example A.2. Comparing a List Attribute Values from a File

First, create a file of possible sn values.
jensen
johnson
johannson
jackson
jorgenson
Then, create a list of entries to compare the values to.
uid=jen200,ou=people,dc=example,dc=com
uid=dsj,ou=people,dc=example,dc=com
uid=matthewjms,ou=people,dc=example,dc=com
uid=john1234,ou=people,dc=example,dc=com
uid=jack.son.1990,ou=people,dc=example,dc=com
Then run the script.
# ldapcompare -D "cn=Directory Manager" -W -p 389 -h server.example.com -x sn:/tmp/surnames.txt -f /tmp/names.txt
comparing type: "sn" value: "jensen" in entry "uid=jen200,ou=people,dc=example,dc=com"
compare TRUE

A.3. Changing Passwords

The ldappasswd command can either set a new user-defined password or generate a new password for an account. Table 19.1, “ldappasswd Options” lists the most important parameters for setting passwords through the command line. Other settings (for bind information, connection information, or other command settings) may be required and are listed in the OpenLDAP manpages.
# ldappasswd -x -D bind_dn -W -p server_port -h server_hostname [-A | -a oldPassword] [-S | -s newPassword] [user]

Important

Password change operations must be run over a secure connection, such as TLS, Start TLS, or SASL. For information on how to configure TLS for LDAP clients, see Section 9.8.4, “Authenticating Using a Certificate”.
For a list of password operation-related parameters for ldapasswd, see Table 19.1, “ldappasswd Options”.

Example A.3. Directory Manager Changing a User's Password Over TLS

The Directory Manager changes the password of the user uid=tuser1,ou=People,dc=example,dc=com to new_password over TLS.
# ldappasswd -D "cn=Directory Manager" -W -ZZ -p 389 -h server.example.com -x -s new_password "uid=tuser1,ou=People,dc=example,dc=com"

Example A.4. Directory Manager Generating a User's Password

The Directory Manager generates the password of the user uid=tuser2,ou=People,dc=example,dc=com over TLS.
# ldappasswd -D "cn=Directory Manager" -W -ZZ -p 389 -h server.example.com -x "uid=tuser2,ou=People,dc=example,dc=com"

Example A.5. User Changing His Own Password

A user, tuser3, changes the password from old_newpassword to new_password over TLS.
# ldappasswd -p 389 -h server.example.com -ZZ -x -D "uid=tuser3,ou=People,dc=example,dc=com" -W -a old_password -s new_password

Example A.6. User Authenticating with DIGEST_MD5 and Changing His Password

A user, jsmith, authenticates with GSS-API and changes the password to new_password.
# ldappasswd -p 389 -h server.example.com -O noplain,minssf=1,maxbufsize=512 -Y GSSAPI -U "dn:uid=jsmith,ou=people,dc=example,dc=com" -R EXAMPLE.COM -W -s new_password

Example A.7. User Already Authenticated by Kerberos Prompts for a New Password

A user, who has already authenticated by Kerberos, prompts for the new password. This is not performed over TLS.
# ldappasswd -p 389 -h server.example.com -O noplain,minssf=1,maxbufsize=512 -I

A.4. Generating LDAP URLs

LDAP URLs are used in a variety of different configuration areas and operations: referrals and chaining, replication, synchronization, ACIs, and indexing, as a starting list. Constructing accurate LDAP URLs is critical, because incorrect URLs may connect to the wrong server or simply cause operations to fail. Additionally, all OpenLDAP tools allow the -H option to pass an LDAP URL instead of other connection information (like the host name, port, subtree, and search base).

Note

LDAP URLs are described in Appendix C, LDAP URLs.
The ldapurl command manages URL in two ways:
  • Deconstruct a given LDAP URL into its constituent element
  • Construct a new, valid LDAP URL from given elements
The parameters for working with URLs are listed in Table A.1, “ldapurl Parameters”; the full list of parameters are in the OpenLDAP manpages.

Table A.1. ldapurl Parameters

Option Description
For Deconstructing a URL
-H "URL" Passes the LDAP URL to break down into elements.
For Constructing a URL
-a attributes Gives a comma-separated attributes that are specifically returned in search results.
-b base Sets the search base or subtree for the URL.
-f filter Sets the search filter to use.
-h hostname Gives the Directory Server's host name.
-p port Gives the Directory Server's port.
-S ldap|ldaps|ldapi Gives the protocol to use to connect, such as ldap, ldaps, or ldapi.
-s scope Gives the search scope.

Example A.8. Deconstructing an LDAP URL

ldapurl uses the -H option to feed in an existing LDAP URL, and the tool returns the elements of the URL in a neat list:
# ldapurl -H "ldap://:389/dc=example,dc=com?cn,sn?sub?(objectclass=inetorgperson)"
scheme: ldap
port: 389
dn: dc=example,dc=com
selector: cn
selector: sn
scope: sub
filter: (objectclass=inetorgperson)

Example A.9. Constructing an LDAP URL

The most useful application of ldapurl is to construct a valid LDAP URL manually. The Directory Server Console has tools to develop valid URLs for areas like ACIs and referrals, but very complex configurations or scripted operations may require administrators to manually construct the URL. Using ldapurl ensures that the URL is valid.
ldapurl accepts the normal connection parameters of all LDAP client tools and additional ldapsearch arguments for search base, scope, and attributes, but this tool never connects to a Directory Server instance, so it does not require any bind information. It accepts the connection and search settings and feeds them in as elements to the URL.
ldapurl -a cn,sn -b dc=example,dc=com -s sub -f "(objectclass=inetorgperson)"

ldap://:389/dc=example,dc=com?cn,sn?sub?(objectclass=inetorgperson)

Appendix B. LDAP Data Interchange Format

Red Hat Directory Server (Directory Server) uses the LDAP Data Interchange Format (LDIF) to describe a directory and directory entries in text format. LDIF is commonly used to build the initial directory database or to add large numbers of entries to the directory all at once. In addition, LDIF is also used to describe changes to directory entries. For this reason, most of Directory Server's command-line utilities rely on LDIF for either input or output.
Because LDIF is a text file format, LDIF files can be created using virtually any language. All directory data is stored using the UTF-8 encoding of Unicode. Therefore, the LDIF files created must also be UTF-8 encoded.
For information on using LDIF to modify directory entries, see Chapter 3, Managing Directory Entries.

B.1. About the LDIF File Format

LDIF consists of one or more directory entries separated by a blank line. Each LDIF entry consists of an optional entry ID, a required distinguished name, one or more object classes, and multiple attribute definitions.
The LDIF format is defined in RFC 2849, The LDAP Data Interchange Format (LDIF). Directory Server is compliant with this standard.
The basic form of a directory entry represented in LDIF is as follows:
dn: distinguished_name 
objectClass: object_class 
objectClass: object_class 
...
 attribute_type[;subtype]:attribute_value
...
  • Every LDIF entry must have a DN and at least one object class definition.
  • Include any attributes required by the object classes defined for the entry.
  • All other attributes and object classes are optional.
  • Object classes and attributes can be specified in any order.
  • The space after the colon is optional.
Table B.1, “LDIF Fields” describes the LDIF fields shown in the previous definition.

Table B.1. LDIF Fields

Field Definition
[id] Optional. A positive decimal number representing the entry ID. The database creation tools generate this ID automatically. Never add or edit this value yourself.
dn: distinguished_name Specifies the distinguished name for the entry.
objectClass: object_class Specifies an object class to use with this entry. The object class identifies the types of attributes, or schema, allowed and required for the entry. See the Red Hat Directory Server 10 Configuration, Command, and File Reference for a list of standard object classes and Chapter 12, Managing the Directory Schema for information on customizing the schema.
attribute_type Specifies a descriptive attribute to use with the entry. The attribute should be defined either in the schema. See the Red Hat Directory Server 10 Configuration, Command, and File Reference for a list of standard attributes and Chapter 12, Managing the Directory Schema for information on customizing the schema.
[subtype] Optional. Specifies subtype, language, binary, or pronunciation. Use this tag to identify the language in which the corresponding attribute value is expressed or whether the attribute value is binary or a pronunciation of an attribute value. For information on attribute subtypes, see Section 3.2.3.5, “Adding an Attribute Subtype”. For a complete list of the supported subtypes tags, see Table D.1, “Supported Language Subtypes”.
attribute_value Specifies the attribute value to be used with the attribute type.

Note

The LDIF syntax for representing a change to an entry in the directory is different from the syntax described in Table B.1, “LDIF Fields”. For information on using LDIF to modify directory entries, see Chapter 3, Managing Directory Entries.

B.2. Continuing Lines in LDIF

In LDIF files, a line can be broken and continued (called folded) by indenting the continued portion of the line by exactly one space. For example, the following two statements are identical:
dn: cn=Jake Lupinski,dc=example,dc=com

dn: cn=Jake Lup
 inski,dc=exa
 mple,dc=com
It is not required to break and continue LDIF lines. However, doing so may improve the readability of the LDIF file. The usual convention is that an LDIF file does not contain more than 78 columns of text.

B.3. Representing Binary Data

Binary data, such as a JPEG image, is represented in LDIF using one of two methods, standard LDIF notation or base-64 encoding.

B.3.1. Standard LDIF Notation

Standard LDIF notation uses the lesser than (<) symbol to indicate that the data are binary. For example:
jpegphoto: < file:/path/to/photo
With this standard notation, it is not necessary to specify the ldapmodify -b parameter. However, standard notation requires that the following line be added to the beginning of the LDIF file or the LDIF update statements:
version: 1
For example:
# ldapmodify -x -D userDN -W

version: 1
dn: cn=Barney Fife,ou=People,dc=example,dc=com
changetype: modify
add: usercertificate
usercertificate;binary: < file: BarneysCert

B.3.2. Base-64 Encoding

Binary data can be converted to base-64, which can be used in LDIF files, for a variety of data, from images to TLS certificates. Base 64-encoded data are identified by using the :: symbol. For example:
jpegPhoto::encoded_data 
In addition to binary data, other values that must be base-64 encoded include the following:
  • Any value that begins with a colon (:) or a space.
  • Any value that contains non-ASCII data, including new lines.
Use the ldif command-line utility with the -b parameter to convert binary data to LDIF format:
# ldif -b attribute_name 
attribute_name is the name of the attribute to which the binary data is supplied. The binary data is read from standard input and the results are written to standard output. Thus, use redirection operators to select input and output files.
The ldif command-line utility will take any input and format it with the correct line continuation and appropriate attribute information. The ldif utility also assesses whether the input requires base-64 encoding. For example:
# ldif -b jpegPhoto <  mark.jpg > out.ldif
This example takes a binary file containing a JPEG-formatted image and converts it into LDIF format for the attribute jpegPhoto. The output is saved to out.ldif.
The -b option specifies that the ldif utility should interpret the entire input as a single binary value. If -b is not present, each line is considered to be a separate input value.

B.4. Specifying Directory Entries Using LDIF

Many types of entries can be stored in the directory. This section concentrates on three of the most common types of entries used in a directory: domain, organizational unit, and organizational person entries.
The object classes defined for an entry are what indicate whether the entry represents a domain or domain component, an organizational unit, an organizational person, or some other type of entry. For a complete list of the object classes that can be used by default in the directory and a list of the most commonly used attributes, see the Red Hat Directory Server 10 Configuration, Command, and File Reference.

B.4.1. Specifying Domain Entries

Directories often have at least one domain entry. Typically this is the first, or topmost, entry in the directory. The domain entry often corresponds to the DNS host and domain name for your directory. For example, if the Directory Server host is called ldap.example.com, then the domain entry for the directory is probably named dc=ldap,dc=example,dc=com or simply dc=example,dc=com.
The LDIF entry used to define a domain appears as follows:
dn: distinguished_name 
objectClass: top
objectClass: domain
dc: domain_component_name
 list_of_optional_attributes 
...
The following is a sample domain entry in LDIF format:
dn: dc=example,dc=com
objectclass: top
objectclass: domain
dc: example
description: Fictional example company
Each element of the LDIF-formatted domain entry is defined in Table B.2, “LDIF Elements in Domain Entries”.

Table B.2. LDIF Elements in Domain Entries

LDIF Element Description
dn: distinguished_name Required. Specifies the distinguished name for the entry.
objectClass: top Required. Specifies the top object class.
objectClass: domain Specifies the domain object class. This line defines the entry as a domain or domain component. See the Red Hat Directory Server 10 Configuration, Command, and File Reference for a list of the attributes that can be used with this object class. -->
dc: domain_component Attribute that specifies the domain's name. The server is typically configured during the initial setup to have a suffix or naming context in the form dc=hostname,dc=domain,dc=toplevel. For example, dc=ldap,dc=example,dc=com. The domain entry should use the leftmost dc value, such as dc: ldap. If the suffix were dc=example,dc=com, the dc value is dc: example. Do not create the entry for dn: dc=com unless the server has been configured to use that suffix.
list_of_attributes Specifies the list of optional attributes to maintain for the entry. See the Red Hat Directory Server 10 Configuration, Command, and File Reference for a list of the attributes that can be used with this object class.

B.4.2. Specifying Organizational Unit Entries

Organizational unit entries are often used to represent major branch points, or subdirectories, in the directory tree. They correspond to major, reasonably static entities within the enterprise, such as a subtree that contains people or a subtree that contains groups.
The organizational unit attribute that is contained in the entry may also represent a major organization within the company, such as marketing or engineering. However, this style is discouraged. Red Hat strongly encourages using a flat directory tree.
There is usually more than one organizational unit, or branch point, within a directory tree.
The LDIF that defines an organizational unit entry must appear as follows:
dn: distinguished_name 
objectClass: top
objectClass: organizationalUnit
ou: organizational_unit_name
 list_of_optional_attributes 
...
The following is a sample organizational unit entry in LDIF format:
dn: ou=people,dc=example,dc=com
objectclass: top
objectclass: organizationalUnit
ou: people
description: Fictional example organizational unit
Table B.3, “LDIF Elements in Organizational Unit Entries” defines each element of the LDIF-formatted organizational unit entry.

Table B.3. LDIF Elements in Organizational Unit Entries

LDIF Element Description
dn: distinguished_name Specifies the distinguished name for the entry. A DN is required. If there is a comma in the DN, the comma must be escaped with a backslash (\), such as dn: ou=people,dc=example,dc=com.
objectClass: top Required. Specifies the top object class.
objectClass: organizationalUnit Specifies the organizationalUnit object class. This line defines the entry as an organizational unit. See the Red Hat Directory Server 10 Configuration, Command, and File Reference for a list of the attributes available for this object class.
ou: organizational_unit_name Attribute that specifies the organizational unit's name.
list_of_attributes Specifies the list of optional attributes to maintain for the entry. See the Red Hat Directory Server 10 Configuration, Command, and File Reference for a list of the attributes available for this object class.

B.4.3. Specifying Organizational Person Entries

The majority of the entries in the directory represent organizational people.
In LDIF, the definition of an organizational person is as follows:
dn: distinguished_name 
objectClass: top
objectClass: person
objectClass: organizationalPerson
objectClass: inetOrgPerson
cn: common_name 
sn: surname
 list_of_optional_attributes
The following is an example organizational person entry in LDIF format:
dn: uid=bjensen,ou=people,dc=example,dc=com
objectclass: top
objectclass: person
objectclass: organizationalPerson
objectclass: inetOrgPerson
cn: Babs Jensen
sn: Jensen
givenname: Babs
uid: bjensen
ou: people
description: Fictional example person
telephoneNumber: 555-5557
userPassword: {SSHA}dkfljlk34r2kljdsfk9
Table B.4, “LDIF Elements in Person Entries” defines each aspect of the LDIF person entry.

Table B.4. LDIF Elements in Person Entries

LDIF Element Description
dn: distinguished_name Required. Specifies the distinguished name for the entry. For example, dn: uid=bjensen,ou=people,dc=example,dc=com. If there is a comma in the DN, the comma must be escaped with a backslash (\).
objectClass: top Required. Specifies the top object class.
objectClass: person Specifies the person object class. This object class specification should be included because many LDAP clients require it during search operations for a person or an organizational person.
objectClass: organizationalPerson Specifies the organizationalPerson object class. This object class specification should be included because some LDAP clients require it during search operations for an organizational person.
objectClass: inetOrgPerson Specifies the inetOrgPerson object class. The inetOrgPerson object class is recommended for the creation of an organizational person entry because this object class includes the widest range of attributes. The uid attribute is required by this object class, and entries that contain this object class are named based on the value of the uid attribute. See the Red Hat Directory Server 10 Configuration, Command, and File Reference for a list of the attributes available for this object class.
cn: common_name Specifies the person's common name, which is the full name commonly used by the person. For example, cn: Bill Anderson. At least one common name is required.
sn: surname Specifies the person's surname, or last name. For example, sn: Anderson. A surname is required.
list_of_attributes Specifies the list of optional attributes to maintain for the entry. See the Red Hat Directory Server 10 Configuration, Command, and File Reference for a list of the attributes available for this object class.

B.5. Defining Directories Using LDIF

The contents of an entire directory can be defined using LDIF. Using LDIF is an efficient method of directory creation when there are many entries to add to the directory.
To create a directory using LDIF:
  1. Create an ASCII file containing the entries to add in LDIF format.
    Make sure each entry is separated from the next by an empty line. Use just one line between entries, and make sure the first line of the file is not be blank, or else the ldapmodify utility will exit. For more information, see Section B.4, “Specifying Directory Entries Using LDIF”.
  2. Begin each file with the topmost, or root, entry in the database.
    The root entry must represent the suffix or sub-suffix contained by the database. For example, if the database has the suffix dc=example,dc=com, the first entry in the directory must be dn: dc=example,dc=com.
    For information on suffixes, see the "Suffix" parameter described in the Red Hat Directory Server Configuration, Command, and File Reference.
  3. Make sure that an entry representing a branch point in the LDIF file is placed before the entries to create under that branch.
    For example, to place an entry in a people and a group subtree, create the branch point for those subtrees before creating entries within those subtrees.

    Note

    The LDIF file is read in order, so parent entries must be listed before the child entries.
  4. Create the directory from the LDIF file using one of the following methods:
    • Initializing the database through the Directory Server Console. Use this method if there is a small database to import (less than 10,000 entries). See Section 6.1.2, “Importing a Database from the Console”.

      Warning

      This method is destructive and will erase any existing data in the suffix.
    • ldif2db or ldif2db.pl command-line utility. Use this method if there is a large database to import (more than 10,000 entries). See Section 6.1.4.1, “Importing Using the ldif2db Command-Line Script”.
      • ldif2db cannot be used if the server is running.
      • ldif2db.pl can only be used if the server is running.

      Warning

      This method is destructive and will erase any existing data in the suffix.
    • ldapmodify command-line utility with the -a parameter. Use this method if a new subtree is being added to an existing database or there is existing data in the suffix which should not be deleted. Unlike the other methods for creating the directory from an LDIF file, Directory Server must be running before a subtree can be added using ldapmodify. See Section 3.1.3, “Adding an Entry”.

Example B.1. LDIF File Example

This LDIF file contains one domain, two organizational units, and three organizational person entries:
dn: dc=example,dc=com
objectclass: top
objectclass: domain
dc: example
description: Fictional example domain

dn: ou=People,dc=example,dc=com
objectclass: top
objectclass: organizationalUnit
ou: People
description: Fictional example organizational unit
tel: 555-5559

dn: cn=June Rossi,ou=People,dc=example,dc=com
objectClass: top
objectClass: person
objectClass: organizationalPerson
objectClass: inetOrgPerson
cn: June Rossi
sn: Rossi
givenName: June
mail: rossi@example.com
userPassword: {sha}KDIE3AL9DK
ou: Accounting
ou: people
telephoneNumber: 2616
roomNumber: 220

dn: cn=Marc Chambers,ou=People,dc=example,dc=com
objectClass: top
objectClass: person
objectClass: organizationalPerson
objectClass: inetOrgPerson
cn: Marc Chambers
sn: Chambers
givenname: Marc
mail: chambers@example.com
userPassword: {sha}jdl2alem87dlacz1
telephoneNumber: 2652
ou: Manufacturing
ou: People
roomNumber: 167

dn: cn=Robert Wong,ou=People,example.com Corp,dc=example,dc=com
objectClass: top
objectClass: person
objectClass: organizationalPerson
objectClass: inetOrgPerson
cn: Robert Wong
cn: Bob Wong
sn: Wong
givenname: Robert
givenname: Bob
mail: bwong@example.com
userPassword: {sha}nn2msx761
telephoneNumber: 2881
roomNumber: 211
ou: Manufacturing
ou: people

dn: ou=Groups,dc=example,dc=com
objectclass: top
objectclass: organizationalUnit
ou: groups
description: Fictional example organizational unit

B.6. Storing Information in Multiple Languages

If the directory contains a single language, it is not necessary to do anything special to add a new entry to the directory. However, if an organization is multinational, it may be necessary to store information in multiple languages so that users in different locales can view directory information in their own language.
When information in the directory is represented in multiple languages, the server associates language tags with attribute values. When a new entry is added, the attribute values used in the RDN (relative distinguished name, the naming attribute) must be provided without any language codes.
Multiple languages can be stored for a single attribute. In this case, the attribute types are the same, but each value has a different language code.
For a list of the languages supported by Directory Server and their associated language tags, see Section D.2, “Supported Locales”.

Note

The language tag has no effect on how the string is stored within the directory. All object class and attribute strings are stored using UTF-8. The user is responsible for converting the data used in the LDIF to UTF-8. The iconv or uconv command provided by most operating systems can be used to convert data from the native characterset into UTF-8.
For example, Example Corporation has offices in the United States and France and wants employees to be able to view directory information in their native language. When adding directory entries, the directory administrator chooses to provide attribute values in both English and French. When adding a directory entry for a new employee, Babs Jensen, the administrator does the following:
  1. The administrator creates a file, street.txt, with the French street address value:
    1 rue de l'Université
  2. The file contents are then converted to UTF-8:
    # iconv -t UTF-8 -o output.txt street.txt
  3. The following LDIF entry is created using the UTF-8 value of the street address value for streetAddress;lang-fr.
    dn: uid=bjensen,ou=people,dc=example,dc=com
    objectclass: top
    objectclass: person
    objectclass: organizationalPerson
    name: Babs Jensen
    cn: Babs Jensen
    sn: Jensen
    uid: bjensen
    streetAddress: 1 University Street
    streetAddress;lang-en: 1 University Street
    streetAddress;lang-fr:: AasljdoaAJASI023909jaASJaonasd0ADS
    preferredLanguage: fr
    The double colons after the attribute name and subtype indicate that the value is binary base-64 encoded.
Users accessing this directory entry with an LDAP client with the preferred language set to English will see the address 1 University Street. Users accessing the directory with an LDAP client with the preferred language set to French will see the address 1 rue de l'Université.

Appendix C. LDAP URLs

LDAP URLs identify the Red Hat Directory Server instance, similarly to the way site URLs identify a specific website or web page. There are three common times when the LDAP URL of the Directory Server instance is used:
  • The LDAP URL is used to identify the specific Directory Server instance when the Directory Server is accessed using a web-based client.
  • LDAP URLs are used to configure Directory Server referrals.
  • LDAP URLs are used to configure access control instructions.

Note

The LDAP URL format is described in RFC 4516, which is available at http://www.ietf.org/rfc/rfc4516.txt.

C.1. Components of an LDAP URL

LDAP URLs have the following syntax:
ldap[s]://hostname:port/base_dn?attributes?scope?filter
It is also possible to use IPv4 or IPv6 addresses instead of the host name.
The ldap:// protocol is used to connect to LDAP servers over unsecured connections, and the ldaps:// protocol is used to connect to LDAP servers over TLS connections. Table C.1, “LDAP URL Components” lists the components of an LDAP URL.

Note

The LDAP URL format is described in RFC 4516, which is available at http://www.ietf.org/rfc/rfc4516.txt.

Table C.1. LDAP URL Components

Component Description
host name Name (or IPv4 or IPv6 address) of the LDAP server. For example, ldap.example.com or 192.0.2.90.
port Port number of the LDAP server (for example, 696). If no port is specified, the standard LDAP port (389) or LDAPS port (636) is used.
base_dn Distinguished name (DN) of an entry in the directory. This DN identifies the entry that is the starting point of the search. If no base DN is specified, the search starts at the root of the directory tree.
attributes The attributes to be returned. To specify more than one attribute, use commas to separate the attributes; for example, cn,mail,telephoneNumber. If no attributes are specified in the URL, all attributes are returned.
scope The scope of the search, which can be one of these values:
base retrieves information only about the distinguished name (base_dn) specified in the URL.
one retrieves information about entries one level below the distinguished name (base_dn) specified in the URL. The base entry is not included in this scope.
sub retrieves information about entries at all levels below the distinguished name (base_dn) specified in the URL. The base entry is included in this scope.
If no scope is specified, the server performs a base search.
filter Search filter to apply to entries within the specified scope of the search. If no filter is specified, the server uses the filter (objectClass=*).
The attributes, scope, and filter components are identified by their positions in the URL. Even if no attributes are specified, the question marks still must be included to delimit that field.
For example, to specify a subtree search starting from dc=example,dc=com that returns all attributes for entries matching (sn=Jensen), use the following LDAP URL:
ldap://ldap.example.com/dc=example,dc=com??sub?(sn=Jensen)
The two consecutive question marks, ??, indicate that no attributes have been specified. Since no specific attributes are identified in the URL, all attributes are returned in the search.

C.2. Escaping Unsafe Characters

Any unsafe characters in the URL need to be escaped, or substituted with a special sequence of characters.
For example, a space is an unsafe character that must be represented as %20 within the URL. Thus, the distinguished name o=example.com corporation must be encoded as o=example.com%20corporation.
The following table lists the characters that are considered unsafe within URLs and provides the associated escape characters to use in place of the unsafe character:
Unsafe Character Escape Characters
space %20
< %3c
> %3e
" %22
# %23
% %25
{ %7b
} %7d
| %7c
\ %5c
^ %5e
~ %7e
[ %5b
] %5d
` %60

C.3. Examples of LDAP URLs

Note

The LDAP URL format is described in RFC 4516, which is available at http://www.ietf.org/rfc/rfc4516.txt.
Example 1

The following LDAP URL specifies a base search for the entry with the distinguished name dc=example,dc=com.

ldap://ldap.example.com/dc=example,dc=com
  • Because no port number is specified, the standard LDAP port number (389) is used.
  • Because no attributes are specified, the search returns all attributes.
  • Because no search scope is specified, the search is restricted to the base entry dc=example,dc=com.
  • Because no filter is specified, the directory uses the default filter (objectclass=*).
Example 2

The following LDAP URL retrieves the postalAddress attribute of the entry with the DN dc=example,dc=com:

ldap://ldap.example.com/dc=example,dc=com?postalAddress
  • Because no search scope is specified, the search is restricted to the base entry dc=example,dc=com.
  • Because no filter is specified, the directory uses the default filter (objectclass=*).
Example 3

The following LDAP URL retrieves the cn, mail, and telephoneNumber attributes of the entry for Barbara Jensen:

ldap://ldap.example.com/cn=Barbara%20Jensen,dc=example,dc=com?cn,mail,telephoneNumber
  • Because no search scope is specified, the search is restricted to the base entry cn=Barbara Jensen,dc=example,dc=com.
  • Because no filter is specified, the directory uses the default filter (objectclass=*).
Example 4

The following LDAP URL specifies a search for entries that have the surname Jensen and are at any level under dc=example,dc=com:

ldap://ldap.example.com/dc=example,dc=com??sub?(sn=Jensen)
  • Because no attributes are specified, the search returns all attributes.
  • Because the search scope is sub, the search encompasses the base entry dc=example,dc=com and entries at all levels under the base entry.
Example 5

The following LDAP URL specifies a search for the object class for all entries one level under dc=example,dc=com:

ldap://ldap.example.com/dc=example,dc=com?objectClass?one
  • Because the search scope is one, the search encompasses all entries one level under the base entry dc=example,dc=com. The search scope does not include the base entry.
  • Because no filter is specified, the directory uses the default filter (objectclass=*).

Note

The syntax for LDAP URLs does not include any means for specifying credentials or passwords. Search requests initiated through LDAP URLs are unauthenticated, unless the LDAP client that supports LDAP URLs provides an authentication mechanism.

Appendix D. Internationalization

Red Hat Directory Server allows users to store, manage, and search for entries and their associated attributes in a number of different languages. An internationalized directory can be an invaluable corporate resource, providing employees and business partners with immediate access to the information they need in languages they understand.
Directory Server supports all international charactersets by default because directory data is stored in UTF-8. Further, Directory Server can use specified matching rules and collation orders based on language preferences in search operations.

Note

ASCII characters are required for attribute and object class names.

D.1. About Locales

Directory Server provides support for multiple languages through the use of locales. A locale identifies language-specific information about how users of a specific region, culture, or custom expect data to be presented, including how data of a given language is interpreted and how data is to be sorted, or collated.
In addition, the locale information indicates what code page should be used to represent a given language. A code page is an internal table that the operating system uses to relate keyboard keys to character font screen displays.
More specifically, a locale defines four things:
  • Collation order. The collation order provides language and cultural-specific information about how the characters of a given language are to be sorted. It identifies things like the sequence of the letters in the alphabet, how to compare letters with accents to letters without accents, and if there are any characters that can be ignored when comparing strings. The collation order also takes into account culture-specific information about a language, such as the direction in which the language is read (left to right, right to left, or up and down).
  • Character type. The character type distinguishes alphabetic characters from numeric or other characters. For example, in some languages, the pipe (|) character is considered punctuation while in others it is considered alphabetic. In addition, it defines the mapping of upper-case to lower-case letters.
  • Monetary format. The monetary format specifies the monetary symbol used by a specific region, whether the symbol goes before or after its value, and how monetary units are represented.
  • Time/date format. The time and date format indicates the customary formatting for times and dates in the region. The time and date format indicates whether dates are customarily represented in the mm/dd/yy (month, day, year) or dd/mm/yy (day, month, year) format and specifies what the days of the week and month are in a given language. For example, the date January 10, 1996, is represented as 10. leden 1996 in Czech and 10 janvier 1996 in French.
Because a locale describes cultural, customary, and regional differences in addition to mechanical language differences, the directory data can both be translated into the specific languages understood by users as well as be presented in a way that users in a given region expect.

D.2. Supported Locales

When performing directory operations that require that a locale be specified, such as a search operation, use a language tag or a collation order object identifier (OID).
A language tag is a string that begins with the two-character lowercase language code that identifies the language, as defined in ISO Standard 639. If necessary to distinguish regional differences in language, the language tag may also contain a two-character string for the country code, as defined in ISO Standard 3166. The language code and country code are separated by a hyphen. For example, the language tag used to identify the British English locale is en-GB.
An object identifier (OID) is a decimal number used to uniquely identify an object, such as an attribute or object class. The OIDs for searching or indexing an internationalized directory identify specific collation orders supported by the Directory Server. For example, the OID 2.16.840.1.113730.3.3.2.17.1 identifies the Finnish collation order.
When performing an international search in the directory, use either the language tag or the OID to identify the collation order to use. However, when setting up an international index, the OIDs must be used. For more information on indexing, see Chapter 13, Managing Indexes.
For a list of language tags and OIDs supported by the Directory Server, see the /etc/dirsrv/config/slapd-collations.conf file.

D.3. Supported Language Subtypes

Language subtypes can be used by clients to determine specific values for which to search. For more information on using language subtypes, see Section 3.2.3.5, “Adding an Attribute Subtype”. Table D.1, “Supported Language Subtypes” lists the supported language subtypes for Directory Server.

Table D.1. Supported Language Subtypes

Language Tag Language
af Afrikaans
be Belorussian
bg Bulgarian
ca Catalan
cs Czech
da Danish
de German
el Greek
en English
es Spanish
eu Basque
fi Finnish
fo Faroese
fr French
ga Irish
gl Galician
hr Croatian
hu Hungarian
id Indonesian
is Icelandic
it Italian
ja Japanese
ko Korean
nl Dutch
no Norwegian
pl Polish
pt Portuguese
ro Romanian
ru Russian
sk Slovak
sl Slovenian
sq Albanian
sr Serbian
sv Swedish
tr Turkish
uk Ukrainian
zh Chinese

D.4. Searching an Internationalized Directory

When performing search operations, the Directory Server can sort the results based on any language for which the server has a supporting collation order. For a listing of the collation orders supported by the directory, see Section D.2, “Supported Locales”.

Note

An LDAPv3 search is required to perform internationalized searches. Therefore, do not set the LDAPv2 option on the call for ldapsearch.
This section focuses using matching rule filters to return international attribute values. For more information on general ldapsearch syntax, see Section 14.4, “LDAP Search Filters”. For information on searching internationalized directories using the Users and Groups portion of the Red Hat Console, see the online help.

D.4.1. Matching Rule Formats

The matching rule filters for internationalized searches can be represented in any several ways, and which one should be used is a matter of preference:
  • As the OID of the collation order for the locale on which to base the search.
  • As the language tag associated with the collation order on which to base the search.
  • As the OID of the collation order and a suffix that represents a relational operator.
  • As the language tag associated with the collation order and a suffix that represents a relational operator.
The syntax for each of these options is discussed in the following sections:

D.4.1.1. Using an OID for the Matching Rule

Each locale supported by the Directory Server has an associated collation order OID. For a list of OIDs supported by the Directory Server, see the /etc/dirsrv/config/slapd-collations.conf file.
The collation order OID can be used in the matching rule portion of the matching rule filter as follows:
 attr:OID:=(relational_operator value)
The relational operator is included in the value portion of the string, separated from the value by a single space. For example, to search for all departmentNumber attributes that are at or after N4709 in the Swedish collation order, use the following filter:
departmentNumber:2.16.840.1.113730.3.3.2.46.1:=>= N4709

D.4.1.2. Using a Language Tag for the Matching Rule

Each locale supported by the Directory Server has an associated language tag. For a list of language tags supported by the Directory Server, see the /etc/dirsrv/config/slapd-collations.conf file.
The language tag can be used in the matching rule portion of the matching rule filter as follows:
 attr:language-tag:=(relational_operator value)
The relational operator is included in the value portion of the string, separated from the value by a single space. For example, to search the directory for all description attributes with a value of estudiante using the Spanish collation order, use the following filter:
cn:es:== estudiante

D.4.1.3. Using an OID and Suffix for the Matching Rule

As an alternative to using a relational operator-value pair, append a suffix that represents a specific operator to the OID in the matching rule portion of the filter. Combine the OID and suffix as follows:
 attr: OID+suffix:=value
For example, to search for businessCategory attributes with the value softwareprodukte in the German collation order, use the following filter:
businessCategory:2.16.840.1.113730.3.3.2.7.1.3:=softwareprodukte
The .3 in the previous example is the equality suffix.
For a list of OIDs supported by the Directory Server, see the /etc/dirsrv/config/slapd-collations.conf file. For a list of relational operators and their equivalent suffixes, see Table D.2, “Search Types, Operators, and Suffixes”.

D.4.1.4. Using a Language Tag and Suffix for the Matching Rule

As an alternative to using a relational operator-value pair, append a suffix that represents a specific operator to the language tag in the matching rule portion of the filter. Combine the language tag and suffix as follows:
 attr: language-tag+suffix:=value
For example, to search for all surnames that come at or after La Salle in the French collation order, use the following filter:
sn:fr.4:=La Salle
For a list of language tags supported by the Directory Server, see the /etc/dirsrv/config/slapd-collations.conf file. For a list of relational operators and their equivalent suffixes, see Table D.2, “Search Types, Operators, and Suffixes”.

D.4.2. Supported Search Types

The Directory Server supports the following types of international searches:
  • equality (=)
  • substring (*)
  • greater-than (>)
  • greater-than or equal-to (>=)
  • less-than (<)
  • less-than or equal-to (<=)
Approximate, or phonetic, and presence searches are supported only in English.
As with a regular ldapsearch search operation, an international search uses operators to define the type of search. However, when invoking an international search, either use the standard operators (=, >=, >, <, <=) in the value portion of the search string, or use a special type of operator, called a suffix (not to be confused with the directory suffix), in the matching rule portion of the filter. Table D.2, “Search Types, Operators, and Suffixes” summarizes each type of search, the operator, and the equivalent suffix.

Table D.2. Search Types, Operators, and Suffixes

Search Type Operator Suffix
Less-than < .1
Less-than or equal-to <= .2
Equality = .3
Greater-than or equal-to >= .4
Greater-than > .5
Substring * .6

D.4.3. International Search Examples

The following sections show examples of how to perform international searches on directory data. Each example gives all the possible matching rule filter formats so that you can become familiar with the formats and select the one that works best.

D.4.3.1. Less-Than Example

Performing a locale-specific search using the less-than operator (<), or suffix (.1) searches for all attribute values that come before the given attribute in a specific collation order.
For example, to search for all surnames that come before the surname Marquez in the Spanish collation order, any of the following matching rule filters would work:
sn:2.16.840.1.113730.3.3.2.15.1:=< Marquez
...
sn:es:=< Marquez
...
sn:2.16.840.1.113730.3.3.2.15.1.1:=Marquez
...
sn:es.1:=Marquez

D.4.3.2. Less-Than or Equal-to Example

Performing a locale-specific search using the less-than or equal-to operator (<=), or suffix (.2) searches for all attribute values that come at or before the given attribute in a specific collation order.
For example, to search for all room numbers that come at or before room number CZ422 in the Hungarian collation order, any of the following matching rule filters would work:
roomNumber:2.16.840.1.113730.3.3.2.23.1:=<= CZ422
...
roomNumber:hu:=<= CZ422
...
roomNumber:2.16.840.1.113730.3.3.2.23.1.2:=CZ422
...
roomNumber:hu.2:=CZ422

D.4.3.3. Equality Example

Performing a locale-specific search using the equal to operator (=), or suffix (.3) searches for all attribute values that match the given attribute in a specific collation order.
For example, to search for all businessCategory attributes with the value softwareprodukte in the German collation order, any of the following matching rule filters would work:
businessCategory:2.16.840.1.113730.3.3.2.7.1:==softwareprodukte
...
businessCategory:de:== softwareprodukte
...
businessCategory:2.16.840.1.113730.3.3.2.7.1.3:=softwareprodukte
...
businessCategory:de.3:=softwareprodukte

D.4.3.4. Greater-Than or Equal-to Example

Performing a locale-specific search using the greater-than or equal-to operator (>=), or suffix (.4) searches for all attribute values that come at or after the given attribute in a specific collation order.
For example, to search for all localities that come at or after Québec in the French collation order, any of the following matching rule filters would work:
locality:2.16.840.1.113730.3.3.2.18.1:=>= Québec
...
locality:fr:=>= Québec
...
locality:2.16.840.1.113730.3.3.2.18.1.4:=Québec
...
locality:fr.4:=Québec

D.4.3.5. Greater-Than Example

Performing a locale-specific search using the greater-than operator (>), or suffix (.5) searches for all attribute values that come at or before the given attribute in a specific collation order.
For example, to search for all mail hosts that come after host schranka4 in the Czech collation order, any of the following matching rule filters would work:
mailHost:2.16.840.1.113730.3.3.2.5.1:=> schranka4
...
mailHost:cs:=> schranka4
...
mailHost:2.16.840.1.113730.3.3.2.5.1.5:=schranka4
...
mailHost:cs.5:=schranka4

D.4.3.6. Substring Example

Performing an international substring search searches for all values that match the given pattern in the specified collation order.
For example, to search for all user IDs that end in ming in the Chinese collation order, any of the following matching rule filters would work:
uid:2.16.840.1.113730.3.3.2.49.1:=* *ming
...
uid:zh:=* *ming
...
uid:2.16.840.1.113730.3.3.2.49.1.6:=* *ming
..
uid:zh.6:=* *ming
Substring search filters that use DN-valued attributes, such as modifiersName or memberOf, do not always match entries correctly if the filter contains one or more space characters.
To work around this problem, use the entire DN in the filter instead of a substring, or ensure that the DN substring in the filter begins at an RDN boundary; that is, make sure it starts with the type= part of the DN. For example, this filter should not be used:
(memberOf=*Domain Administrators*)
But either one of these will work correctly:
(memberOf=cn=Domain Administrators*)
...
(memberOf=cn=Domain Administrators,ou=Groups,dc=example,dc=com)

D.5. Troubleshooting Matching Rules

International collation order matching rules may not behave consistently. Some forms of matching-rule invocation do not work correctly, producing incorrect search results. For example, the following rules do not work:
# ldapsearch -x -p 389 -D "uid=userID,ou=people,dc=example,dc=com" -W -b "dc=example,dc=com" "sn:2.16.840.1.113730.3.3.2.7.1:=passin"

ldapsearch -x -p 389 -D "uid=userID,ou=people,dc=example,dc=com" -W -b "dc=example,dc=com" "sn:de:=passin"
However, the rules listed below will work (note the .3 before the passin value):
# ldapsearch -x -p 389 -D "uid=userID,ou=people,dc=example,dc=com" -W -b "dc=example,dc=com" "sn:2.16.840.1.113730.3.3.2.7.1.3:=passin"

ldapsearch -x -p 389 -D "uid=userID,ou=people,dc=example,dc=com" -W -b "dc=example,dc=com" "sn:de.3:=passin"

Appendix E. Managing the Administration Server

E.1. Introduction to Red Hat Administration Server

Identity management and directory services with Red Hat Directory Server use three components, working in tandem:
  • A Java-based management console
  • An administration server which also functions as a web server
  • An LDAP directory server
Interactions between the Console, Administration Server and Directory Server

Figure E.1. Interactions between the Console, Administration Server and Directory Server

The Administration Server processes configuration requests for Directory Server instances and performs many common server tasks, such as stopping and starting server instances. Directory services are usually divided into two categories: configuration databases which store the Console and Administration Server settings and some Directory Server configuration and user databases which contain user and group information. These databases can be kept in the same Directory Server instance, but it is also possible to break these services into separate Directory Server instances. In that case, a Directory Server instance's configuration are stored in a separate Directory Server, called the Configuration Directory Server, and user data is stored in the User Directory Server. Because the Administration Server processes server configuration requests for Red Hat Directory Server, the Configuration Directory Server and User Directory Server instances are both defined in the Administration Server configuration.
As a web server, the Administration Server provides all of the online functions of the Directory Server, including handling connections to the Console and hosting web applications such as Admin Express. Clients connect to the Administration Server both over secure and standard connections, since the Administration Server supports both HTTP or HTTPS, if TLS is enabled.
When Red Hat Directory Server or Red Hat Certificate System (which depends on Red Hat Directory Server) is installed, then the Administration Server is automatically installed and configured as well. There can be multiple Directory Server instances and multiple Certificate System subsystems on a single machine, and all use the same instance of Administration Server.
There can be only one Administration Server per machine. This single Administration Server instance can handle multiple instances of Directory Server and other clients which can use the Administration Server, like Red Hat Certificate System.
When the Console is opened to manage an instance of Directory Server or Certificate System, even if the Console is on a different machine than the server instance being managed, it contacts the local Administration Server instance to perform the requested tasks. For example, Administration Server can execute programs to modify the server and application settings that are stored in the configuration directory or to change the port number that a server listens to.
The Administration Server itself can be managed through its own Java-based interface, by editing its configuration files, or through command-line tools.

E.2. Administration Server Configuration

The Administration Server is a separate server from Red Hat Directory Server or Red Hat Certificate System, although they work interdependently. The Administration Server processes, file locations, and configuration options are also separate. This chapter covers the Administration Server information, including starting and stopping the Administration Server, enabling TLS, viewing logs, and changing Administration Server configuration properties, such as the server port number.

E.2.1. File Locations

E.2.2. Opening the Administration Server Console

There is a simple script to launch the main Console. On Red Hat Enterprise Linux, run the following:
# /usr/bin/redhat-idm-console
When the login screen opens, the Administration Server prompts for the user name, password, and Administration Server location. The Administration Server location is a URL; for a standard connection, this has the http: prefix for a standard HTTP protocol. If TLS is enabled, then this uses the https: prefix for the secure HTTPS protocol.
Login Box

Figure E.2. Login Box

Note

It is possible to send the Administration Server URL and port with the start script. For example:
# /usr/bin/redhat-idm-console -a http://localhost:9830
The a option is a convenience, particularly for logging into a Directory Server for the first time. On subsequent logins, the URL is saved. If the Administration Server port number is not passed with the redhat-idm-console command, then the server prompts for it at the Console login screen.
This opens the main Console window. To open the Administration Server Console, select the Administration Server instance from the server group on the left, and then click the Open at the top right of the window.
The Administration Server Console

Figure E.3. The Administration Server Console

Note

Make sure that the Oracle Java Runtime Environment (JRE) or OpenJDK version 1.8.0 is set in the PATH before launching the Console. Run the following to see if the Java program is in the PATH and to get the version and vendor information:
java -version

E.2.3. Viewing Logs

Log files monitor activity for Administration Server and can help troubleshoot server problems. Administration Server logs use the Common Logfile Format, a broadly supported format that provides information about the server.
Administration Server generates two kinds of logs:
  • Access logs. Access logs show requests to and responses from the Administration Server. By default, the file is located at /var/log/dirsrv/admin-serv/access.
  • Error logs. Error logs show messages for errors which the server has encountered since the log file was created. It also contains informational messages about the server, such as when the server was started and who tried unsuccessfully to log on to the server. By default, the file is located at /var/log/dirsrv/admin-serv/error.
The logs can be viewed through Administration Server Console or by opening the log file.

E.2.3.1. Viewing the Logs through the Console

  1. Open the Administration Server management window.
  2. Click the Configuration tab.
  3. Expand the Logs directory, and click the log file name, either Accesses or Error.

E.2.3.2. Viewing Logs in the Command Line

The access log, by default, is at /var/log/dirsrv/admin-serv/error. To view the access log, open it in an editor such as vi.
Access logs show connections to the Administration Server based on the IP address of the client, the user name, and the method that the request was sent. Each line has the following format:
ip_address - bind_DN [timestamp -0500] "GET|POST cgi" HTTP_response bytes
Example logs are shown in Example E.1, “Example Access Logs”.

Example E.1. Example Access Logs

127.0.0.1 - cn=Directory Manager [23/Dec/2008:19:32:52.157345975 -0500] "GET /admin-serv/authenticate HTTP/1.0" 200 338
192.168.123.121 - cn=Directory Manager [23/Dec/2008:19:33:14.453724501 -0500] "POST /admin-serv/tasks/Configuration/ServerSetup HTTP/1.0" 200 244
192.168.123.121 - cn=Directory Manager [23/Dec/2008:19:33:16.573485244 -0500] "GET /admin-serv/tasks/Configuration/ReadLog?op=count&name=access HTTP/1.0" 200 10
The error log, by default, is at /var/log/dirsrv/admin-serv/errors. To view the error log, open it in an editor such as vi.
Error logs record any problem response from the Administration Server. Like the access log, error logs also records entries based the client's IP address, along with the type of error message, and the message text:
[timestamp] [severity] [client ip_address error_message
The severity message indicates whether the error is critical enough for administrator intervention. [warning], [error], and [critical] require immediate administrator action. Any other severity means the error is informational or for debugging.
Example logs are shown in Example E.2, “Example Error Logs”.

Example E.2. Example Error Logs

[24/Mar/2017:11:14:27.110314677 +0100] - NOTICE - ldbm_back_start - total cache size: 417775616 B; 
[24/Mar/2017:11:14:27.165466639 +0100] - INFO - dblayer_start - Resizing db cache size: 1519206400 -> 132562944
[24/Mar/2017:11:14:27.650899322 +0100] - INFO - slapd_daemon - slapd started.  Listening on All Interfaces port 389 for LDAP requests
[24/Mar/2017:11:14:29.620268885 +0100] - WARN - modify_config_dse - Modification of attribute "aci" is not allowed, ignoring!

E.2.3.3. Changing the Log Name in the Console

The access and error log files' names can be changed to rotate the files. This rotation has to be done manually to create new files if the existing log files become too large.
  1. Open the Administration Server management window.
  2. Click the Configuration tab.
  3. Click Logs in the left panel.
  4. In the Logs window on the right, enter the new log file name.

    Warning

    The path to the log file is absolute and cannot be changed.
  5. Click OK to save the changes.
  6. Open the Tasks tab, and click the Restart Server button to restart the server and apply the changes.

E.2.3.4. Changing the Log Location in the Command Line

The access and error log files' names and locations can be changed to rotate the files. This rotation has to be done manually to create new files if the existing log files become too large. The location can be changed if the default location in /var/log/dirsrv/admin-serv does not meet the application needs.
The Administration Server configuration is stored in two locations. The main entry is an LDAP entry in the Configuration Directory Server's o=NetscapeRoot database. The other is the console.conf file. Changing the log settings requires changing both settings.
  1. Edit the Administration Server configuration entry in the Configuration Directory Server.
    1. Get the name of the Administration Server entry. Since the Administration Server entry has a special object class, nsAdminConfig, it is possible to search for the entry using that object class to retrieve the DN.
      # ldapsearch -D "cn=Directory Manager" -W -p 389 -h server.example.com -x -b "o=NetscapeRoot" "(objectclass=nsAdminConfig)" dn  
      
      version:1
      dn: cn=configuration,cn=admin-serv-example,cn=Red Hat Administration Server,cn=Server Group,cn=server.example.com,ou=example.com,o=NetscapeRoot
    2. The Administration Server entry can be edited using ldapmodify. The access and error log settings are stored in the nsAccessLogs and nsErrorLogs attributes, respectively. For example:
      # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
      
      dn: cn=configuration,cn=admin-serv-example,cn=Red Hat Administration Server,cn=Server Group,cn=server.example.com,ou=example.com,o=NetscapeRoot
      changetype:modify
      replace:nsAccessLog
      nsAccessLog:/var/log/dirsrv/admin-serv/access_new
      Hit Enter twice to submit the operation, and then Control+C to close ldapmodify.
  2. Open the Administration Server configuration directory.
    # cd /etc/dirsrv/admin-serv
  3. Edit the console.conf file. For the access log, edit the path and filename in the CustomLog parameter. For the error log, edit the path and filename in the ErrorLog parameter.
    CustomLog /var/log/dirsrv/admin-serv/access_new common
    ErrorLog /var/log/dirsrv/admin-serv/error_new
    Leave the term common after the access log path; this means that the access log is in the Common Log Format.
  4. Restart the Administration Server.
    # systemctl restart dirsrv-admin.service

E.2.3.5. Setting the Logs to Show Hostnames Instead of IP Addresses

By default, the logs show the IP address of the clients which connect to the Administration Server. This is faster for the Administration Server, since it does not have to do a DNS lookup for every connection. It is possible to set the Administration Server to perform a DNS lookup so that host names are used in the logs. Along with being friendlier to read and search, using host names instead of IP addresses also removes some unnecessary error messages about being unable to resolve host names.
To configure the Administration Server to perform DNS lookups:
  1. Edit the console.conf file for the Administration Server.
    # cd /etc/dirsrv/admin-serv
    # vim console.conf
  2. Set the HostnameLookups parameter to on. By default, this is turned off, so that IP addresses are recorded in logs instead of host names.
    HostnameLookups on

E.2.4. Changing the Port Number

The port number specifies where an instance of Administration Server listens for messages.
The default port number for Administration Server is set when the instance is first installed and the configuration script, such as setup-ds-admin.pl, is run. The default port number is 9830, although if that number is in use, then the setup program will use a randomly-generated number larger than 1024 or one can assign any port number between 1025 and 65535.

E.2.4.1. Changing the Port Number in the Console

  1. Open the Administration Server management window.
  2. Click the Configuration tab.
  3. Click the Network tab.
  4. Enter the port number for the Administration Server instance in the Port field. The Administration Server port number has a default number of 9830.
  5. Click OK.
  6. Open the Tasks tab, and click the Restart Server button to restart the server and apply the changes.
  7. Close the Console, and then restart the Console, specifying the new Administration Server port number in the connection URL.

E.2.4.2. Changing the Port Number in the Command Line

The port number for the Administration Server is 9830 by default.
The Administration Server configuration is stored in two locations. The main entry is an LDAP entry in the Configuration Directory Server's o=NetscapeRoot database. The other is the console.conf file. Changing the port number requires changing both settings.
  1. Edit the Administration Server configuration entry in the Configuration Directory Server.
    1. Get the name of the Administration Server entry. Since the Administration Server entry has a special object class, nsAdminConfig, it is possible to search for the entry using that object class to retrieve the DN.
      # ldapsearch -D "cn=Directory Manager" -W -p 389 -h server.example.com -x -b "o=NetscapeRoot" "(objectclass=nsAdminConfig)" dn  
      
      version:1
      dn: cn=configuration,cn=admin-serv-example,cn=Red Hat Administration Server,cn=Server Group,cn=server.example.com,ou=example.com,o=NetscapeRoot
    2. The Administration Server entry can be edited using ldapmodify. The port number is set in the nsServerPort attribute. For example:
      # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
      
      dn: cn=configuration,cn=admin-serv-example,cn=Red Hat Administration Server,cn=Server Group,cn=server.example.com,ou=example.com,o=NetscapeRoot
      changetype:modify
      replace:nsServerPort
      nsServerPort:10030
      Hit Enter twice to submit the operation, and then Control+C to close ldapmodify.
  2. Open the Administration Server configuration directory.
    # cd /etc/dirsrv/admin-serv
  3. Edit the Listen parameter in the console.conf file.
    Listen 0.0.0.0:10030
  4. Restart the Administration Server.
    # systemctl restart dirsrv-admin.service

E.2.5. Setting Host Restrictions

Connection restrictions specify which hosts are allowed to connect to the Administration Server. You can list these hosts by DNS name, IP address, or both. Only host machines listed within the connection restriction parameters are allowed to connect to the Administration Server. This setting allows wildcards within a domain or an IP address range to make setting connection restrictions simpler.

E.2.5.1. Setting Host Restrictions in the Console

  1. Open the Administration Server management window.
  2. Click the Configuration tab.
  3. Click the Network tab.
  4. The Connection Restrictions area displays a list of hosts allowed to connect to the Administration Server. The drop-down list specifies whether the list entries are added by DNS name or by IP address. The list is evaluated first by host names, and then by IP addresses.
  5. Click the Add button to add another host to the list of allowed computers. To add a host name, make sure the drop-down list at the top reads Host Names to allow; to add an IP address, select IP Addresses to allow.
  6. Fill in the host information, either the host name or an IPv4 or IPv6 address.
    The * wildcard can be used to specify a group of hosts. For instance, *.example.com allows all machines in the example.com domain to access the instance. Entering 205.12.*. allows all hosts whose IP addresses begin with 205.12 to access the instance.
    When specifying IP address restrictions, include all three separating dots. If you do not, the Administration Server returns an error message.
  7. Click OK to close the Add... dialog box, and then click the Save button to save the new host.
  8. Open the Tasks tab, and click the Restart Server button to restart the server and apply the changes.
To change the information for a host or IP address listed, click the Edit button and change the given information. To remove an allowed host or IP address, select the host from the list, and click Remove. Administration Server.

E.2.5.2. Setting Host Restrictions in the Command Line

Host restrictions sets rules for what network clients can connect to the Administration Server and, therefore, to services which use the Administration Server. There are two kinds of host restrictions, restrictions based on the host or domain name and restrictions based on the IP address.
The Administration Server host restrictions are set in the main configuration entry in the Configuration Directory Server's o=NetscapeRoot database. There are two attributes for setting host restrictions, nsAdminAccessAddresses and nsAdminAccessHosts for IP addresses and host names, respectively.

Note

The Administration Server supports both IPv4 and IPv6 addresses.
The Administration Server entry can be edited using ldapmodify.
To set host restrictions:
  1. Get the name of the Administration Server entry. Since the Administration Server entry has a special object class, nsAdminConfig, it is possible to search for the entry using that object class to retrieve the DN.
    # ldapsearch -D "cn=Directory Manager" -W -p 389 -h server.example.com -x -b "o=NetscapeRoot" "(objectclass=nsAdminConfig)" dn  
    
    version:1
    dn: cn=configuration,cn=admin-serv-example,cn=Red Hat Administration Server,cn=Server Group,cn=server.example.com,ou=example.com,o=NetscapeRoot
  2. To set IP address-based restrictions, edit the nsAdminAccessAddresses attribute. Either IPv4 or IPv6 addresses can be used.
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn: cn=configuration,cn=admin-serv-example,cn=Red Hat Administration Server,cn=Server Group,cn=server.example.com,ou=example.com,o=NetscapeRoot
    changetype:modify
    replace:nsAdminAccessAddresses
    nsAdminAccessAddresses:72.5.*.*
    Hit Enter twice to submit the operation, and then Control+C to close ldapmodify.
    The nsAdminAccessAddresses value can use wildcards to allow ranges. Either IPv4 or IPv6 addresses can be used.
    For example, to allow all IP addresses:
    nsAdminAccessAddresses:*
    To allow only a subset of addresses on a local network:
    nsAdminAccessAddresses:192.168.123.*
  3. To set host name or domain-based restrictions, edit the nsAdminAccessHosts attribute.
    # ldapmodify -D "cn=Directory Manager" -W -p 389 -h server.example.com -x
    
    dn: cn=configuration,cn=admin-serv-example,cn=Red Hat Administration Server,cn=Server Group,cn=server.example.com,ou=example.com,o=NetscapeRoot
    changetype:modify
    replace:nsAdminAccessHosts
    nsAdminAccessHosts:*.example.com
    Hit Enter twice to submit the operation, and then Control+C to close ldapmodify.
  4. Restart the Administration Server to apply the changes.
    # systemctl restart dirsrv-admin.service

E.2.6. Changing the Admin User's Name and Password

During installation, you are asked to enter a user name and password for the Configuration Administrator, the user authorized to access and modify the entire configuration directory. The Configuration Administrator entry is stored in the directory under the following DN:
uid=userID,ou=Administrators,ou=TopologyManagement,o=NetscapeRoot
The Configuration Administrator's user name and password are managed through the Directory Server and are represented in an LDAP entry; this is described in the Red Hat Directory Server Administration Guide.
During installation, the Configuration Administrator's user name and password are used to automatically create the Administration Server Administrator. This user can perform a limited number of administrative tasks, such as starting, stopping, and restarting servers in a local server group. The Administration Server Administrator is created for the purpose of logging into the Console when the Directory Server is not running.
The Administration Server Administrator does not have an LDAP entry; it exists only as an entity in a local configuration file, /etc/dirsrv/admin-serv/admpw.
Even though they are created at the same time during installation, and are identical at that time, the Configuration Administrator and Administration Server Administrator are two separate entities. If you change the user name or password for one in the Console, the Console does not automatically make the same changes for the other.
The Administration Server Administrator has full access to all configuration settings in the Administration Server. The information for the admin user is set on the Access tab in the Console.

Note

The Administration Server administrator user name and password are stored in the /etc/dirsrv/admin-serv/admpw file. For example:
admin:{SHA}W6ph5Mm5Pz8GgiULbPgzG37mj9g=
The password is encrypted and cannot be changed directly in the admpw file. The user name can be changed in this file, but cannot be used to log into the Console unless the password is updated in the Console first. For this reason, it is better to edit the Administration Server Administrator user name and password only through the Administration Server Console.
To change the Administration Server Administrator's ID or password:
  1. Open the Administration Server management window.
  2. Click the Configuration tab.
  3. Click the Access tab.
  4. Change the admin user's name or password. The user name is the ID given for logging into the Administration Server.
  5. Click Save.

E.2.7. Working with TLS

The Administration Server can run over HTTPS (secure HTTP) if TLS is enabled on the server. There are steps to enabling TLS:
  1. Generating and submitting a certificate request.
  2. Receiving and installing the certificate.
  3. Trusting the certificate authority (CA) which issued the certificate.
  4. Changing the Administration Server configuration to allow TLS connections.

E.2.7.1. Managing Certificates for Administration Server

To request and install certificates for the Administration Server Console, follow the procedures for the Directory Server Console. See:

Important

If you use:
  • The graphical user interface, perform the steps in the Manage Certificates menu of the Administration Server Console instead of the Directory Server Console.
  • The command line, use the /etc/dirsrv/admin-serv/ instead of the /etc/dirsrv/slapd-instance_name/ directory when you manage the Network Security Services (NSS) database.
E.2.7.1.1. Using the Directory Server Private Key and Certificate for the Admin Server
The Administration Server and Directory Server use different PKI databases. When the Certificate Request Wizard for the Directory Server is passed through, the automatically generated private key is stored in the Directory Server's PKI database. However, because the same private key does not exist in both databases, a certificate issued for one cannot be installed in the other database.
Run the following commands to export the private key and certificate of the Directory Server, and import them into the Administration Server's database:
  1. Shut down the Administration Server:
    # systemctl stop dirsrv-admin
  2. Shut down the Directory Server:
    # systemctl stop dirsrv@instance
  3. List the contents of the Directory Server NSS database:
    # certutil -L -d /etc/dirsrv/admin-serv/
    
    Certificate Nickname                     Trust Attributes
                                             SSL,S/MIME,JAR/XPI
    
    Demo CA                                  CT,,
    server-cert                              u,u,u
  4. Export the private key and certificate with the name server-cert from the Directory Server's PKI database:
    # pk12util -o /tmp/keys.pk12 -n server-cert -d /etc/dirsrv/slapd-instance/
    Enter Password or Pin for "NSS Certificate DB":
    Enter password for PKCS12 file: 
    Re-enter password: 
    pk12util: PKCS12 EXPORT SUCCESSFUL
    Enter the Directory Server's key store password, and optionally a new password for the temporarily exported file when prompted.
  5. Import the private key and certificate into the Administration Server's PKI database:
    # pk12util -i /tmp/keys.pk12 -d /etc/dirsrv/admin-serv/
    Enter a password which will be used to encrypt your keys.
    The password should be at least 8 characters long,
    and should contain at least one non-alphabetic character.
    
    Enter new password: 
    Re-enter password: 
    Enter password for PKCS12 file:
    pk12util: PKCS12 IMPORT SUCCESSFUL
    pk12util asks you to set a password for the Administration Server's key store. If you already had set one to this database before, you are prompted to enter this password instead. If you set a password on the exported file in the previous step, you are additionally asked to enter this one as well.
  6. Delete the temporarily exported file:
    # rm /tmp/keys.pk12
  7. Trust the Demo CA:
    # certutil -M -d /etc/dirsrv/admin-serv/ -n "Demo CA" -t CT,,
  8. Start the Directory Server:
    # systemctl start dirsrv@instance
  9. Start the Administration Server:
    # systemctl start dirsrv-admin

E.2.7.3. Creating a Password File for the Administration Server

Normally, if TLS is enabled, the server prompts for a security password when the Administration Server is restarted:
Starting dirsrv-admin:
Please enter password for "internal" token:
The Administration Server can use a password file when TLS is enabled so that the server restarts silently, without prompting for the security password.

Warning

This password is stored in clear text within the password file, so its usage represents a significant security risk. Do not use a password file if the server is running in an unsecured environment.
  1. Open the Administration Server configuration directory.
    # cd /etc/dirsrv/admin-serv
  2. Create a password file named password.conf. The file should include a line with the token name and password, in the form token:password. For example:
    internal:secret
    For the NSS software crypto module (the default software database), the token is always called internal.
    The password file should be owned by the Administration Server user and set to read-only by the Administration Server user, with no access to any other user (mode 0400).

    Note

    To find out what the Administration Server user ID is, run grep in the Administration Server configuration directory:
    # cd /etc/dirsrv/admin-serv
    
    # grep \^User console.conf
  3. In the /etc/dirsrv/admin-serv directory, edit the nss.conf file to point to the location of the new password file.
    #   Pass Phrase Dialog:
    #   Configure the pass phrase gathering process.
    #   The filtering dialog program (`builtin' is a internal
    #   terminal dialog) has to provide the pass phrase on stdout.
    NSSPassPhraseDialog  file://etc/dirsrv/admin-serv/password.conf
  4. Restart the Administration Server:
    # systemctl restart dirsrv-admin.service
After TLS is enabled, then the Administration Server can only be connected to using HTTPS. All of the previous HTTP (standard) URLs for connecting to the Administration Server and its services no longer work. This is true whether connecting to the Administration Server using the Console or using a web browser.

E.2.8. Changing Directory Server Settings

The Administration Server stored information about the Directory Server Configuration Directory (which stores the instance configuration information) and the Directory Server User Directory (which stores the actual directory entries). These can be the same directory instance, but they do not have to be. The settings for both of those databases can be edited in the Administration Server configuration so that it communicates with a different Directory Server instance.

E.2.8.1. Changing the Configuration Directory Host or Port

Configuration data are stored under o=NetscapeRoot in the Configuration Directory. The configuration database contains server settings such as network topology information and server instance entries. When server configuration changes are stored in the configuration directory subtree.

Warning

Changing the Directory Server host name or port number impacts the rest of the servers in the server group. Changing a setting here means the same change must be made for every server in the server group.
  1. Open the Administration Server management window.
  2. Click the Configuration tab.
  3. Click the Configuration DS tab.
  4. Set the Configuration Directory Server connection information.
    • The LDAP Host is the host name, IPv4, or IPv6 address of the Configuration Directory Server machine.
    • The LDAP Port is the port number to use for the Directory Server instance. The regular LDAP port is 389; the default LDAPS (secure) port number is 636.
    • Check the Secure Connection check box to use the secure port. Before checking this box, make sure that the Configuration Directory Server has enabled TLS.
  5. Click Save.

E.2.8.2. Changing the User Directory Host or Port

The user directory is used for authentication, user management, and access control. It stores all user and group data, account data, group lists, and access control instructions (ACIs).
There can be multiple user directories in a single deployment because using multiple user directories enhances overall performance for organizations which are geographically spread out, which have high usage, or have discrete divisions which benefit from individual directories.
Administration Server can be configured to authenticate users against multiple user directories.
To change the information for the user directory:
  1. Open the Administration Server management window.
  2. Click the Configuration tab.
  3. Click the User DS tab.
  4. Set the User Directory Server connection information.
  5. Edit the user directory information.
    The Use Default User Directory radio button uses the default user directory associated with the domain. To use multiple Directory Server instances or to use a different instance, select the Set User Directory radio button and set the required information:
    • The LDAP Host and Port field specifies the location of the user directory instance, using the format hostname:port or ip_address:port, with an IPv4 or IPv6 address.
      It is possible to configure multiple locations for the user directory for authentication and other directory functions; separate each location with a space. For example:
      server.example.com:389 alt.example.com:389

      Note

      If more than one location is given in the LDAP Host and Port field, the settings for the remaining fields will apply to all of those instances.
    • Check the Secure Connection box to use TLS to connect to the user directory. Only select this if the Directory Server is already configured to use TLS.
    • Give the User Directory Subtree. For example:
      dc=example,dc=com
      Every location listed in the LDAP Host and Port field must contain that subtree and the subtree must contain the user information.
    • Optionally, enter the Bind DN and Bind Password for the user which connects to the user directory.
  6. Click Save.

Appendix F. Using Admin Express

F.1. Managing Servers in Admin Express

Admin Express provides a quick, simple web-based gateway to do basic management of servers. There are three tasks that can be performed through Admin Express:
  • Stopping and starting the server
  • Checking the server access, error, and audit logs
  • Monitoring the progress and information for replication between Directory Servers

F.1.1. Opening Admin Express

The Administration Server services pages URL is the Administration Server host (host name, IPv4 address, or IPv6 address) and port. For example:
http://ldap.example.com:9830/
The Admin Express page is always available at that URL.

Note

If TLS is enabled on the Administration Server, then the URL must use the prefix https with the same port number. The standard HTTP URLs will not work.
https://ldap.example.com:9830/

F.1.2. Starting and Stopping Servers

On the main Admin Express page, there are buttons to turn servers off and on.
Stopping and Stopping Servers

Figure F.1. Stopping and Stopping Servers

Important

If either the Administration Server or the Configuration Directory Server is turned off through the Admin Express page, then it must be restarted through the command line, not through the Admin Express On/Off buttons because Admin Express requires access to both the Administration Server and Configuration Directory Server in order to function.
Other Directory Server instances can be safely stopped and restarted through Admin Express.

F.1.3. Viewing Server Logs

Admin Express can show and search the access and error logs for Directory Server and Administration Server and the audit logs for the Directory Server.
  1. In the Admin Express page, click the Logs link by the server name.
  2. Select which log type to view, how many lines to return, and any string to search for, and click OK.
Checking Logs

Figure F.2. Checking Logs

F.1.4. Viewing Server Information

The Server Info link on the Admin Express page opens a page with the basic description of the server instance, such as the build number, installation date, and server port number. This is the same information displayed in the Console when an instance is selected.
Checking Server Information

Figure F.3. Checking Server Information

The Directory Server information is located in the /etc/dirsrv/slapd-instance/dse.ldif file; the Administration Server information is located in .conf files in the /etc/dirsrv/admin-serv directory.

F.2. Configuring Admin Express

Admin Express can be edited for the page appearance, but most functionality is controlled through the web server or the Administration Server configuration and should be edited through those servers, not by editing the configuration files directly.

F.2.1. Admin Express File Locations

The directories for all of the Admin Express configuration files are listed in Table F.1, “Admin Express File Directories”; the specific files are described in each section describing the different Admin Express page configurations.

Table F.1. Admin Express File Directories

Directory Description
/etc/dirsrv/admin-serv/ Contains the local.conf, httpd.conf, and other configuration files which define the Administration Server and configure the web server.
/usr/share/dirsrv/html/ Contains the HTML files and graphics used for the Admin Express appearance.

F.2.2. Admin Express Configuration Files

The behavior for Admin Express is mostly set through the web server configuration and should not be edited. The other Admin Express configuration is set through directives which insert data or form fields.
There is not cascading style sheet (CSS) file to centralize the formatting for pages in Admin Express. All formatting is done inline with the tags or through <style> tags in the page head. For information on editing inline tags, see http://directory.fedoraproject.org/docs/389ds/administration/htmlediting.html.

F.2.2.1. Files for the Administration Server Welcome Page

The configuration files for the introductory page for Admin Express is located in the /etc/dirsrv/admin-serv directory. One file sets the formatting, copyright text, and some web application text, admserv.html.
Intro Page Elements

Figure F.4. Intro Page Elements

All of the formatting for the page is set inline. The text files are inserted using the INCLUDEIFEXISTS directive.
  <tr valign="TOP">
    <td> </td>
    <td bgcolor="#9999cc" colspan="4"> <font color="white" size="+1"><font face="Verdana, sans-serif">Services
      for Administrators</font></font></td>
    <td> </td>
  </tr>
  <tr valign="TOP">
    <td> </td>
    <td colspan="4">
      <table border="0" cellspacing="0" cellpadding="0">
        <tr valign="TOP">
          <td><img src="/icons/spacer.gif" width="6" height="6"></td>
          <td></td>
        </tr>
<!-- INCLUDEIFEXISTS admserv_dsgw.html -->
The text files themselves have inline formatting for the inserted table rows.

F.2.2.2. Files for the Replication Status Appearance

There are two pages for monitoring the replication status. The first is for the configuration page, which requires two files:
  • The body of the page, /usr/share/dirsrv/html/monreplication.html
  • The heading of the page, /usr/share/dirsrv/html/htmladmin.html
Monitoring Replication Setup Page Elements

Figure F.5. Monitoring Replication Setup Page Elements

The Replication Status page uses two script-related configuration files:
  • The body of the page, which is configured in the replication monitoring script, /usr/bin/repl-monitor.pl
  • Optionally, the configuration file for the replication monitoring, which can configure the time lag colors with the [colors] section
  • The heading of the page, /usr/share/dirsrv/html/htmladmin.html
Monitoring Replication View Page Elements

Figure F.6. Monitoring Replication View Page Elements

The text for the table headings, labels, and page sections are set in the Perl script. For example:
#Print the header of consumer
   print "\n<tr class=bgColor16>\n";
   print "<th nowrap>Receiver</th>\n";
   print "<th nowrap>Time Lag</th>\n";
   print "<th nowrap>Max CSN</th>\n";
....
   print "</tr>\n";
The styles for the Replication Status page are printed in the Perl script in the <style> tag in the HTML header. Many of the classes are the same as those in the style.css for the other web applications. These can be edited in the Perl script or by uncommenting the stylesheet reference and supplying a CSS file. For example:
 # print the HTML header

   print "Content-type: text/html\n\n";
   print "<!DOCTYPE HTML PUBLIC \"-//W3C//DTD HTML 3.2//EN\"><html>\n";
   print "<head><title>Replication Status</title>\n";
   # print "<link type=text/css rel=stylesheet href=\"master-style.css\">\n";
   print "<style text/css>\n";
   print "Body, p, table, td, ul, li {color: #000000; font-family: Arial, Helvetica, sans-serif; font-size: 12px;}\n";
   print "A {color:blue; text-decoration: none;}\n";
   print "BODY {font-family: Arial, Helvetica, sans-serif}\n";
   print "P {font-family: Arial, Helvetica, sans-serif}\n";
   print "TH {font-weight: bold; font-family: Arial, Helvetica, sans-serif}\n";
   print "TD {font-family: Arial, Helvetica, sans-serif}\n";
   print ".bgColor1  {background-color: #003366;}\n";
   print ".bgColor4  {background-color: #cccccc;}\n";
   print ".bgColor5  {background-color: #999999;}\n";
   print ".bgColor9  {background-color: #336699;}\n";
   print ".bgColor13 {background-color: #ffffff;}\n";
   print ".bgColor16 {background-color: #6699cc;}\n";
   print ".text8  {color: #0099cc; font-size: 11px; font-weight: bold;}\n";
   print ".text28 {color: #ffcc33; font-size: 12px; font-weight: bold;}\n";
   print ".areatitle {font-weight: bold; color: #ffffff; font-family: Arial, Helvetica, sans-serif}\n";
   print ".page-title {font-weight: bold; font-size: larger; font-family: Arial, Helvetica, sans-serif}\n";
   print ".page-subtitle {font-weight: bold; font-family: Arial, Helvetica, sans-serif}\n";

   print "</style></head>\n<body class=bgColor4>\n";

F.2.2.3. Files for the Server Information Page

There are two files formatting the server information page:
  • The body of the page, /usr/share/dirsrv/html/viewdata.html
  • The heading of the page, /usr/share/dirsrv/html/htmladmin.html
Server Information Page Elements

Figure F.7. Server Information Page Elements

The viewdata.html file is very simple, using only the two directives to insert the server data, plus other directives to insert other information. For the Administration Server, the SHOW_DATA directive takes the information from the /etc/dirsrv/admin-serv/local.conf file. For the Directory Server, it takes the data from the /etc/dirsrv/slapd-instance/dse.ldif file. The ID_TITLE is the name of the server instance.
<body text="#000000" bgcolor="#FFFFFF" link="#666699" vlink="#666699" alink="#333366">

<br>
<table BORDER=0 CELLSPACING=2 CELLPADDING=2 WIDTH="100%">
<!-- ID_TITLE -->
<p>
<!-- SHOW_DATA -->
<p>
<font face="PrimaSans BT, Verdana, sans-serif"><font size=-1>Additional Information:</font></font>
<p>
<!-- CHECK_UPGRADE -->
<p>
<!-- SHOW_URL -->
</table>

<!-- HELPBUTTON -->

</body>

F.2.2.4. Files for the Server Logs Page

There are two files formatting the server logs page:
  • The body of the page, /usr/share/dirsrv/html/viewlog.html
  • The heading of the page, /usr/share/dirsrv/html/htmladmin.html
Log View Page Elements

Figure F.8. Log View Page Elements

The page information is set through the inserted directives. The server instance name is set in the ID_TITLE directive. The log is displayed through the ACCESS_LOG directives. The form at the top is formatted with directive pairs, one which sets the descriptive text and the other inserting the field type. For example, this sets the log type menu:
<form method=GET action=ViewLog>
<font face="PrimaSans BT, Verdana, sans-serif"><font size=-1>
<!-- BEGINELEM -->
<!-- ELEM txt="Log to view:            " -->
<!-- LOG_TO_VIEW -->
....
<!-- SUBMIT -->
</font></font>
</form>

F.2.3. Admin Express Directives

The Admin Express directives are HTML comments that are interpreted by the CGI scripts; these directives are used to set form fields and to pull data from the server configuration and log files.

Table F.2. Admin Express Directives

Directive Description Example
ACCESS_LOG Inserts the server log file. <!-- ACCESS_LOG -->
ADMURL <!-- ADMURL -->
BEGINELEM Marks the opening of form input elements. This is always paired with ENDELEM. <!-- BEGINELEM -->
CHECK_UPGRADE <!-- CHECK_UPGRADE -->
ELEM Inserts a text element. This has one argument, txt=, which defines the text to use. <!-- ELEM txt="Field name here: " -->
ELEMADD Inserts a text element. This has one argument, txt=, which defines the text to use. <!-- ELEMADD txt="Field name here: " -->
ENDELEM Marks the ending of form input elements. This is always paired with BEGINELEM. <!-- ENDELEM -->
HELP_BUTTON Inserts a button to open context-specific help. <!-- HELP_BUTTON -->
HELPLINK Inserts a link to the general Admin Express help file. <!-- HELPLINK -->
HIDDEN_ID <!-- HIDDEN_ID -->
ID_TITLE Inserts the name of the server instance, such as admin-serv or example (if the Directory Server instance name is slapd-example) <!-- ID_TITLE -->
INCLUDEIFEXISTS Inserts the contents of the HTML file. The inserted file should include both the text and any HTML markup. <!-- INCLUDEIFEXISTS "file.html" -->
LOG_TO_VIEW Inserts a drop-down menu with the types of logs available to view. <!-- LOG_TO_VIEW -->
NUM_TO_VIEW Inserts a form field to set the number of lines to return. <!-- NUM_TO_VIEW -->
REFRESHINTERVAL Inserts a form field to set the refresh interval (in seconds) for replication monitoring. <!-- REFRESHINTERVAL -->
SERVHOST <!-- SERVHOST -->
SERVPORT <!-- SERVPORT -->
SHOW_DATA Inserts the server data from the configuration file, including the port number, installation date, and build number. <!-- SHOW_DATA -->
SHOW_URL <!-- SHOW_URL -->
SITEROOT <!-- SITEROOT -->
STRING_TO_VIEW Inserts a form field to use to set the search string for the logs. <!-- STRING_TO_VIEW -->
SUBMIT Inserts a three-button set: to save or submit the form; to reset the form; and to open a help topic. <!-- SUBMIT -->

Appendix G. Using the Console

G.1. Overview of the Directory Server Console

Red Hat Management Console is the user interface to manage Red Hat Directory Server and Administration Server configuration and directory information. There is a single main Console window which administers the servers (collected and identified in administration domains). The main Console allows you to open server-specific Consoles to manage the settings and information in individual instances.
This chapter provides an overview of how the Console interacts with the Directory Server and Administration Server and walks through the Console windows and options.

G.1.1. How the Console, Directory Server, and Administration Server Work Together

The Red Hat Console is an independent Java application which works in conjunction with instances of Red Hat Directory Server and Administration Server. Most server management functions are carried out in server-specific console windows for the Directory Server and Administration Server. Red Hat Console is part of a system that manages Red Hat Directory Server instances and the Administration Server and, therefore, information in the directory. Although Red Hat Directory Server, Red Hat Management Console, and Red Hat Administration Server work tightly with one another, each plays a specific role in managing servers, applications, and users.
Red Hat Management Console is the front-end management application for Red Hat Directory Server. It finds all servers and applications registered in the configuration directory, displays them in a graphical interface, and can manage and configure them. The Main Console can also search for, create, and edit user and group entries in the user directory.
The Red Hat Management Console Interface

Figure G.1. The Red Hat Management Console Interface

When a user logs into Red Hat Management Console, the Console connects to the Administration Server over Hypertext Transfer Protocol (HTTP). The Administration Server receives requests to administer the different Directory Server instances and performs the changes to the configuration, such as changing a port number. When a request is sent to the Red Hat Management Console to add or edit user entries, the Console sends a Lightweight Directory Access Protocol (LDAP) message directly to Directory Server to update the user directory.
Simple System Using Red Hat Management Console

Figure G.2. Simple System Using Red Hat Management Console

Red Hat Directory Server stores server and application configuration settings as well as user information. Typically, application and server configuration information is stored in one subtree of Red Hat Directory Server while user and group entries are stored in another subtree. With a large enterprise, however, configuration and user information can be stored in separate instances of Directory Server (which can be on the same host machine or on two different host machines). Figure G.2, “Simple System Using Red Hat Management Console” illustrates a relatively simple Red Hat Directory Server system. As an enterprise grows and needs change, additional hosts and Directory and Admin Servers can be added to the administration domain in the Console, so that a single Console can manage multiple Directory and Admin Servers.
A More Complex System

Figure G.3. A More Complex System

Note

When the terms configuration directory and user directory are used in this guide, they define where the configuration information and the user information is stored, regardless of whether that is in the subtrees of a single instance of Directory Server or in two separate instances of Directory Server.

G.1.2. Red Hat Management Console Menus

There are five menu items in the top menu the Console. The options for each of these menus varies depending on the Console window open (the main Console, Directory Server Console, or Administration Server Console) and the types of objects available in that server area.
Main Console Menus

Figure G.4. Main Console Menus

Table G.1. Console Menus

Menu Description
Console Manages the Console session, such as closing the window or exiting the session entirely.
  • For the main window, this menu also can be used to add and remove admin domain.
  • For the Directory Server Console, this allows people to log in as a different user.
  • For the Administration Server Console, it manages security issues, such as certificates and tokens.
Edit Sets display preferences, for all three Consoles. For the Directory Server Console, this also provides ways to copy, paste, and delete directory entries or text.
View Sets whether to display certain parts of the Console window, such as the top banner, menus, and side navigation panes. This also refreshes the current display. For the Directory Server Console, this menu also sets what parts of the directory or which databases to view.
Object Provides available operations for the active object; this is the same as the right-click menu for the active area or entry.
  • For the main window, this menu simply opens or deletes a server instance.
  • For the Directory Server Console, this provides all of the configuration options for the directory entries, such as advanced property editors or creating new entries.
  • For the Administration Server Console, this opens a configuration editor, starts, and stops the server.
Help Opens context-specific help for the current Console area.

G.1.3. Red Hat Management Console Tabs

There are two tabs in the main Console window:
  • Servers and Applications, for managing the Directory Server and Administration Server instances
  • Users and Groups, for searching for and creating user and group entries within the Directory Server

G.1.3.1. The Servers and Applications Tab

The Servers and Applications tab, by default, has a navigation tree on the left for viewing hosts and Directory and Administration Servers and a center information panel. To access the Directory Server instance, directory information, or Administration Server, open the server resource listed in the navigation tree. The information for the server instance, such as the build number and port number,
The navigation tree displays the Red Hat Directory Server topology, a hierarchical representation of all the resources (such as servers and hosts), that are registered in a configuration directory.
The Servers and Applications Tab

Figure G.5. The Servers and Applications Tab

The top of the topology is the administration domain. An administration domain is a collection of host systems and servers that share the same user directory. The server which hosts Directory Server or Administration Server instances belongs to the admin domain; that is the host.
A server group consists of all Directory Servers that are managed by a common Administration Server. A number of server groups can exist within an administration domain.

G.1.3.2. The Users and Groups Tab

The Users and Groups tab can search for user and group entries in any Directory Server administered by the Console. Any of the returned entries can be edited or deleted through this tab, assuming that the users has the proper access permissions. New entries can also be created through the Users and Groups tab.
The Users and Groups Tab

Figure G.6. The Users and Groups Tab

Switch the directory being searched or where the entries are added through the options in the Users menu, as described in Section G.4.1, “Searching for Users and Groups”.

G.1.4. Server-Specific Consoles

The main Console can open into two server-specific windows to manage the Administration Server and Directory Server. These windows are opened by clicking the server name in the navigation area, and then clicking the Open button in the resources area.

G.1.4.1. The Directory Server Console

The Directory Server Console manages the specific Directory Server instance configuration, including the port number, TLS settings, and logging. The Directory Server Console also manages the directory information (entries) and directory operations like importing and exporting databases, creating suffixes, and extending the schema.
The Directory Server Console

Figure G.7. The Directory Server Console

There are four tabs in the Directory Server Console:
  • Tasks, which has shortcuts to common server operations, including starting and stopping the Directory Server instance, importing and exporting databases, and managing TLS certificates
  • Configuration, which defines all of the server configuration settings, including SASL and TLS authentication, port numbers, schema, replication and synchronization, databases and suffixes, logging, and plug-ins
  • Directory, which access and manages the directory information, including user entries and all group entries, including roles, classes of service, views, and groups
  • Status, which monitors the server performance and displays the different monitoring and performance counters for the Directory Server and databases
Similar to the main Console, the Directory Server Console tabs have a navigation area on the left and a center panel that displays information about the active setting, entry, or database.
The procedures for using the Directory Server Console to manage the Directory Server configuration and directory entries is covered in the Red Hat Directory Server Administration Guide.

G.1.4.2. The Administration Server Console

The Administration Server itself administers the configuration of other servers, especially the configuration and user directories for the server group. The Administration Server Console manages the Administration Server settings and the settings for these two Directory Server directories; whenever the settings are changed in the Directory Server configuration, the modifications must be carried into the Administration Server configuration for the server to properly manage those servers.
The Administration Server Console

Figure G.8. The Administration Server Console

The Administration Server Console is simpler than the Directory Server Console, with only two tabs:
  • Tasks, which has shortcuts to common server operations, including starting and stopping the Administration Server instance, setting up logging, and managing TLS certificates
  • Configuration, which defines all of the Administration Server configuration settings, including TLS authentication, port numbers, and logging, as well as the Configuration Directory Server and User Directory Server settings which the Administration Server uses to connect to the directory services
The procedures for using the Administration Server Console to manage the Administration Server configuration and associated directory services is covered in the Using the Admin Server guide.

G.2. Changing the Console Appearance

The fonts used for different elements in the Console can be edited. The font settings and the location where the font profiles are stored can be customized. The default font settings can be restored easily.
This section also describes how to control other aspects of the appearance of the Console. For example, table columns can be easily rearranged. It is also possible to control which server instances are displayed (called a navigation view) which makes it easy to sort and find server instances.
Access control instructions can be applied to user interface elements, which is discussed in Section G.5, “Setting Access Controls”.

G.2.1. Changing Profile Locations

The Console formatting is stored in profiles. An entry's profiles can be stored locally, which means that they are only available at a specific workstation, or can be stored in the configuration directory, so they are accessible anywhere.
To set the profile location:
  1. Click Edit in the top menu, and choose Preferences.
  2. Click the Settings tab.
  3. Select the radio button for the location to save the settings.
    • In your configuration directory means that the settings are stored in the Directory Server configuration, making them available no matter where you log into the Console.
    • On your computer's hard disk stores the setting profiles locally. This is mainly useful if you want specific, different settings used by default on different Consoles, such as a workstation and a laptop.
  4. Click OK.

G.2.2. Restoring Default Font Settings

  1. Click Edit in the top menu, and choose Preferences.
  2. Click the Settings tab.
  3. Click the Restore Defaults button to revert to the default display settings.
  4. Click OK.

G.2.3. Changing Console Fonts

Different parts of the Console, such as table headings and regular text, have different font settings. The font settings are stored in profiles. The profiles define the font family, size, and formatting for every text element. There can be multiple font profiles available, and the font profiles can be private, such as settings for a specific user or group, or public, so that any user can access them.
The default profile can be edited without having to create new profiles.
To edit or create a font profile:
  1. In the main Red Hat Management Console window, from the Edit menu, choose Preferences.
  2. Click the Fonts tab.
  3. To save the new settings as a new profile, click the Save As button, and fill in the profile name.
    To edit the default (or current) profile, simply begin editing the fonts.
  4. In the Screen Element column, click a screen element to edit, then click the Change Font button.
  5. Edit the font for that specific element. There are three settings which can be changed: the font family, the size, and the formatting (bold or italic).
  6. Click OK to save the profile.
  7. Restart the Console to apply the changes.
To load and use a saved font profile, open the Font tab in the Preference dialog, and simply select the font profile to use and click OK.
To delete a font profile, simply make sure that it is selected from the drop-down menu in the Fonts tab, and click the Remove button.

G.2.4. Reordering Table Columns

The columns in a table can be rearranged by dragging them into a new position.
  1. Click in the table heading.
  2. Still holding down the left mouse button, drag the column to its new location. The other table columns will automatically shift down to their new positions.
  3. When you release the mouse button, the column snaps into its new position.

G.2.5. Customizing the Main Window

Different elements of the main Red Hat Management Console window can be displayed or hidden; this is set by check boxes in the View menu.
There are three parts of the Console which can be hidden: the navigation tree (the smaller panel on the left of the Console window); the decorative background and banner at the top of the Console window; and the status bar at the bottom of the Console.

G.2.6. Working with Custom Views

The Console allows different views to be created to show different server and domain entries in the Red Hat Management Console window. Views show only a defined set of server entries; this makes it easier to maintain large numbers of instances or to have a quick way to perform specific tasks.

G.2.6.1. Creating Custom Views

Custom views show different, defined server instances. Views are either public or private. A public view is visible to any user, while a private view is visible only to the person who created it.
  1. In the View menu, choose Custom View Configuration.
  2. Click New.
  3. Choose whether the new view will be public or private, then click OK.
  4. In the Edit View window, enter a descriptive name for this view.
  5. Select a resource from the Default View navigation tree on the left. Click Copy to list it in the panel on the right and include it in the view.
    To select a range of resources, click the SHIFT key and select the first and last entries; select multiple, separate resources by holding down the Ctrl key and selecting the entries.
To edit a custom view, select it from the list, click the Edit button, and make the changes to the name or resources.
To delete a custom view, select it from the list, and click the Remove button.

G.2.6.2. Switching to a Custom View

Choose the required custom view from the drop-down list on the Servers and Applications tab.
To return to the default view, choose Default View from the drop-down list.

G.2.6.3. Setting Access Permissions for a Public View

  1. From the View menu, choose Custom View Configuration.
  2. Choose a public Custom View from the list and click Access.
  3. Set the access control instructions.
  4. Click OK to save the ACI.
For more information on setting access permissions and creating access control instructions, see Section G.5, “Setting Access Controls”.

G.3. Managing Server Instances

The server instances managed by the Red Hat Management Console are arranged in a hierarchy. At the top is the admin domain. Within the domain are hosts, representing different server machines. Each host has server groups, which identifies an inter-related group of Directory Servers using the same Administration Server instance. The individual Directory Server instances and a single Administration Server instance belong within a server group. There can only be one Administration Server instance per server group.
These high level entries can be created and managed in the Red Hat Management Console.

G.3.1. Editing Domain, Host, Server Group, and Instance Information

The Red Hat Console displays some information about every admin domain, host, group, and server instances. Most of this information — such as the installation date and build number — are not editable, but some information is.
  1. In the Servers and Applications tab, select the entry to modify.
  2. Click Edit.
  3. Edit the instance's information. Every entry has the option to change its name and description. The host, which is the physical machine on which the instances are installed, also has the option of changing the location.
  4. Click OK.

G.3.2. Creating and Removing Admin Domains

An admin domain is a container entry for server groups (and each server group contains Directory Server instances which are configured to work with the same Configuration Directory Server and the same Administration Server, which is also in the server group).

G.3.2.1. Creating and Editing an Admin Domain

To create a new admin domain:
  1. In the top menu, click the Console menu item.
  2. Select Create New Administration Domain.
  3. Fill in the admin domain's information, including information for a new Directory Server instance.
  4. Click OK.
To edit an admin domain, select the entry in the server window and click the Edit button.

Warning

The admin domain settings affect all servers within the domain. Making any changes to the admin domain settings means that all servers in the domain must be restarted.

G.3.2.2. Removing an Admin Domain

To remove an admin domain:
  1. Highlight the admin domain to remove in the navigation tree.
  2. In the top menu, click the Console menu item.
  3. Select Remove Administration Domain.
  4. Click Yes.

Note

Any server group and servers within the domain must be removed before the domain can be deleted.

G.4. Managing Directory Server Users and Groups

Users for both multiple Red Hat Directory Server instances and Administration Server can be created, edited, and searched for in the Red Hat Management Console. The main Console window can also be used to create organizational units and groups and to add entries to the new ous and groups.
Section G.5, “Setting Access Controls” describes how to work with user and group information when setting access privileges and other security information.

G.4.1. Searching for Users and Groups

The Users and Groups searches for directory entries; by default, it looks in the default user directory configured for the Administration Server, but the directory can be changed to any Red Hat Directory Server instance.
To search the directory:
  1. Click the Users and Groups tab.
  2. Enter the search criteria, and click Search.
    • For a simple search, enter all or part of an entry name in the text box. To return all entries, leave the search field blank or enter an asterisk (*).
    • For a more complex or focused search, click the Advanced button, and enter the attributes to search (such as cn, givenname, or ou), the kind of search, and the search term. To add or remove search criteria, click the More and Fewer buttons.
  3. Click Search. Results are displayed in the list box.
To change the search directory:
  1. Click the Users and Groups tab.
  2. In the top menu, select the User menu item, and choose Change Directory.
  3. Fill in the user directory information.
    • User Directory Host. The fully qualified host name for the Directory Server instance.
    • User Directory Port and Secure Connection. The port number for the connection and whether this is a TLS (LDAPS).
    • User Directory Subtree. The DN of the subtree to search in the directory; for example, dc=example,dc=com for the base DN or ou=Marketing, dc=example,dc=com for a subtree.
    • Bind DN and Bind Password. The credentials to use to authenticate to the directory.
  4. Click OK.

G.4.2. Creating Directory Entries

The Red Hat Management Console can be used to add, edit, and delete users, groups, and organization units in the Users and Groups tab. The different kinds of entries and options for creating entries is explained in more detail in the Red Hat Directory Server Administration Guide.

G.4.2.1. Directory and Administrative Users

Note

A user can be added to the Directory Server user database through the Console or a user can be added as an Administration Server administrator. The process is almost identical, with two exceptions:
  • A Directory Server user is added by clicking the Create button, then the Users option, while an administrator is created by selecting the Administrator option.
  • An administrator does not require selecting an organization unit, while the Directory Server user does, because the administrator is automatically added to ou=Groups,ou=Topology,o=NetscapeRoot.
  1. Click the Users and Groups tab.
  2. Click the Create button, and choose User.
    Alternatively, open the User option in the top menu, and choose Create > User.
  3. Select the are in the directory tree under which the entry is created.

    Note

    When creating an administrator, there is no option to select the ou to which to add the user as there is with a regular Directory Server user. This is because the administrator is added to ou=Groups,ou=Topology,o=NetscapeRoot, with the admin users.
    The entry can be added to an ou or a view, if views have been added to the directory.
  4. In the Create User window, enter user information. The Common Name and User ID fields are automatically filled in with the combined values the First Name and Last Name fields. These first, last, and common name fields are required; a password is also required for the user to be able to log into the Directory Server and the Console, but is not a required attribute.
  5. Optionally, click the Languages link on the left, select an alternate language and fill in internationalized values for common attributes.
    This option allows international users to select a language other than English and to represent their names in their preferred language. The pronunciation attribute allows for phonetic searching against the international name attributes.
  6. Click OK.

G.4.2.2. Groups

A group consists of users who share a common attribute or are part of a list. Red Hat Directory Server supports three types of groups: static, dynamic, and certificate. Each group differs by the way in which users, or members, are added to it:
  • A static group has members who are manually added to it, so it is static because the members do not change unless an administrator manually adds or removes users.
  • A dynamic group automatically includes users based on one or more attributes in their entries; the attributes and values are determined using LDAP URLs. For example, a dynamic group can use an LDAP filter which searches for entries which contain the attributes and values st=California and department=sales. As entries are added to the directory with those two attributes, the users are automatically added as members to the dynamic group. If those attributes are removed from the entry, the entry is removed from the group.
  • A certificate group includes all users who have a specific attribute-value pair in the subject name of the certificate. For example, the certificate group could be based on having the string st=California,ou=Sales,ou=West in the subject name. If a user logs onto a server using a certificate with those attributes in his certificate, the user is automatically added to the group and is granted all of the access privileges of that group.
To create a group:
  1. Click the Users and Groups tab.
  2. Click the Create button, and choose Group.
    Alternatively, open the User option in the top menu, and choose Create > Group.
  3. Select the are in the directory tree under which the entry is created.
    The subtree entry can be an ou or a view, if views have been added to the directory.
  4. Enter the group's name and description.
    It is possible to save the new group entry at this point, without adding members. Click OK.
  5. Click the Members link to add members to the group, and click the tab of the type of group membership, Static, Dynamic, or Certificate.
  6. Configure the members. For static groups, manually search for and add users; for dynamic groups, construct the LDAP URL to use to find entries; and for certificate groups, enter the values to search for in user certificate subject names.

Note

The different kinds of groups and how to configure their members are explained in more detail in the Red Hat Directory Server Administration Guide.

G.4.2.3. Organizational Units

An organizational unit can include a number of groups and users. An org unit usually represents a distinct, logical division in an organization, such as different departments or geographical locations. Each organizationalUnitName (ou) is a new subtree branch in the directory tree. This is reflected in the relative distinguished name of the ou, such as ou=People,dc=example,dc=com, which becomes part of the distinguished names of its sub-entries.
  1. Click the Users and Groups tab.
  2. Click the Create button, and choose Organizational Unit.
    Alternatively, open the User option in the top menu, and choose Create > Organizational Unit.
  3. Select the directory subtree under which to locate the new organizational unit.
  4. Fill in the organizational unit information. The Alias offers an alternative name for the organizational unit that can be used instead of the full name.
  5. Click OK.

G.4.3. Modifying Directory Entries

G.4.3.1. Editing Entries

  1. Search for the entry to edit.
    See Section G.4.1, “Searching for Users and Groups” for more information on searching for entries.
  2. Select the entry, and click Edit.
  3. Edit the entry information, and click OK to save the changes.

G.4.3.2. Allowing Sync Attributes for Entries

Red Hat Directory Server and Active Directory synchronization unify some Unix and Windows-specific directory attributes; to carry over a Directory Server entry to Active Directory, the entry must have ntUser attributes. (Likewise, Windows entries must have posixAccount attributes.)
Windows (NT) attributes must an be enabled on entries. By default, these attributes are added manually to individual entries. The user edit windows have links on the left for NT User to allow Directory Server entries to contain Windows-specific attributes for synchronization.
It is also possible to configure the server so that all new entries will automatically possess the ntUser object class; this is described in the Directory Server—Active Directory synchronization chapter of the Red Hat Directory Server Administration Guide.

Note

Any Red Hat Directory Server entry must have the ntUser object class and required attributes added in order to be synchronized to Active Directory.
To enable synchronization:
  1. Select or create a user, and click the NT User link.
  2. Enable the NT account, and check how the entry will be synchronized (meaning, whether a new entry will be created and whether that entry should be deleted on Active Directory if it is delete on Directory Server).
  3. Click OK.

G.4.3.3. Changing Administrator Entries

When the Administration Server is installed, two entries are created with administrator access in the Console. The main entry is the Configuration Administrator, who is authorized to access and modify the entire configuration directory (o=NetscapeRoot). The Configuration Administrator entry is stored in the uid=username, ou=Administrators,ou=TopologyManagement,o=NetscapeRoot entry.
The Configuration Administrator's user name and password are automatically used to create the Administration Server Administrator, who can perform a limited number of tasks, such as starting, stopping, and restarting servers. The Administration Server Administrator is created so that a user can log into the Red Hat Management Console when the Directory Server is not running. The Administration Server Administrator does not have an LDAP entry; it exists in the Administration Server's configuration file, /usr/share/dirsrv/properties/admpw.

Important

Even though they are created at the same time during installation, and are identical at that time, the Configuration Administrator and Administration Server Administrator are two separate entities. If the user name or password is changed for one, Red Hat Management Console does not automatically make the same changes for the other.
G.4.3.3.1. Changing the Configuration Administrator and Password
  1. In the Users and Groups, click Advanced.
  2. Search for the Configuration Administrator. Select the Administrators object, and enter the administrator's user name, Configuration Administrator by default.
  3. Select the Configuration Administrator from the list of search results, and then click Edit.
  4. Change the administrator's uid and password. The uid is the naming attribute used to log into the Console and run commands.
  5. Click OK.

Note

If you are logged into the Console as the Configuration Administrator when you edited the Configuration Administrator entry, update the login information for the directory.
  1. In the Users and Groups tab, click the User menu in the top menu and select Change Directory.
  2. Update the Bind DN and Bind Password fields with the new information for the Configuration Administrator, and click OK.
G.4.3.3.2. Changing the Admin Password
  1. Select the Administration Server in the Servers and Applications tab, and click Open.
  2. Click the Configuration tab, and open the Access tab.
  3. Set the new password.

    Warning

    Do not change the admin user name.
  4. Click Save.
  5. Restart the Administration Server.
    systemctl restart dirsrv-admin.service
G.4.3.3.3. Adding Users to the Configuration Administrators Group
  1. In the Users and Groups tab, click the User menu in the top menu and select Change Directory.
  2. Change to the o=NetscapeRoot subtree, which contains the configuration information and the Configuration Administrators group.
  3. Search for the Configuration Administrators group, and click Edit.
  4. Click the Members link in the left of the edit window.
  5. Click Add, and search for the user to add to the group.

    Note

    Only users in the o=NetscapeRoot database can be added to the Configuration Administrators group. This means that the entry must be created as an administrator, not a regular user, when added through the Console. See Section G.4.2.1, “Directory and Administrative Users”.

G.4.3.4. Removing an Entry from the Directory

  1. Search for the entry to deleted.
    See Section G.4.1, “Searching for Users and Groups” for more information on searching for entries.

    Note

    All entries must be removed from under an organization unit before it can be deleted.
  2. Select the entry in the results list, and click Delete. Click OK to confirm the deletion.

G.5. Setting Access Controls

Access control instructions (ACIs) can be set in the Red Hat Management Console to set limits on what users can see and what operations they can perform on Red Hat Directory Server and Administration Server instances managed in the Console.
ACIs define what operations users can do with a specific instance of Red Hat Directory Server or Administration Server. ACIs set rules on areas of the subtree which can be accessed or modified, what operations are allowed, even what hosts can be used to access the server and what times of day access is allowed.
For Red Hat Management Console, access controls can be used to grant administrative privileges very easily to specific users and to set restrictions on different aspects of the main Console, such as searching the directory, adding and editing users and groups, and editing server or Console settings.

G.5.1. Granting Admin Privileges to Users for Directory Server and Administration Server

Users can be granted administrative privileges, the same as the admin user for the Administration Server and similar to the cn=Directory Manager user in Directory Server (though not exactly the same as the Directory Manager, which is a special user).
  1. Highlight a server in the Console navigation tree.
  2. Select the Object menu, and choose Set Access Permissions.
    Alternatively, right-click the entry, and choose Set Access Permissions.
  3. Click Add to add a new user to the list of administrators for the server. The default users, Directory Manager for the Directory Server and admin for the Administration Server, are not listed in the Set Permissions Dialog box.
  4. Search for the users to add as an administrators. In the results, highlight the selected users, and click Add to add them to the administrators list.
    For more information on searching for users and groups, see Section G.4.1, “Searching for Users and Groups”.
  5. Click OK to add the names to the Set Permissions Dialog list, then click OK again to save the changes and close the dialog.

Note

Granting a user the right to administer a server does not automatically allow that user to give others the same right. To allow a user to grant administrative rights to other users, add that user to the Configuration Administrators group, as described in Section G.4.3.3.3, “Adding Users to the Configuration Administrators Group”.

G.5.2. Setting Access Permissions on Console Elements

There are five elements defined in the Console for access control rules:
  • User and Groups Tab (viewing)
  • User and Groups Tab (editing)
  • Topology Tab (editing)
  • Custom View Tab (editing)
  • Server Security (editing)
By default, each of these Console elements has five inherited ACIs:
  • Enabling anonymous access
  • Default anonymous access
  • Configuration administrator's modifications
  • Enabling group expansions
  • SIE (host) group permissions
These inherited ACIs cannot be edited, but new ACIs can be added for each Console element in addition to these defaults. Additional ACIs can limit anonymous access, for example, and change other permissions within the Red Hat Management Console, which, in turn, affects access to the Directory Server and Administration Server instances.
To create new ACIs:
  1. In the top menu, select Edit and then Preferences.
  2. Select the Console element from the list, and click the Permissions button.
  3. In the ACI Manager window, click the New button.
    The five inherited ACIs are not displayed by default; to see them listed, click the Show inherited ACIs check box.
  4. Configure the ACI by setting, at a minimum, the users to which it applies and the rights which are allowed. To configure the ACI in the wizard (visually):
    1. Enter a name for the ACI in the ACI Name field.
    2. In the Users/Groups tab, click the Add button to open the search window. Search for and add the users to which apply the ACI.
      Select the users from the results list and click the Add button to include them. Click OK to save the list.
    3. In the Rights tab, specify which operations are permitted as part of this ACI.
      To hide a Console element entirely from the selected users, groups, and hosts, click Check None to block any access.
    4. Optionally, set the target entry in the subtree, hostnames, or times of day where the ACI is in effect.
    More complex ACIs may not be able to be edited visually; in those cases, click the Edit Manually button, and configure the ACI entry directly.
    Use the Check syntax button to validate the ACI.
  5. Click OK to save the ACI.
  6. Restart Red Hat Management Console to apply the new ACI.

Index

A

access control
and directory manager, Setting Access Controls on Directory Manager
compatibility with earlier versions, Compatibility with Previous Releases
logging information, Logging Access Control Information
roles, Using Roles Securely
viewing
get effective rights, Checking Access Rights on Entries (Get Effective Rights)
Access Control
to navigation tree, Granting Admin Privileges to Users for Directory Server and Administration Server
access log
changing location and name
in the command line, Changing the Log Location in the Command Line
in the Console, Changing the Log Name in the Console
configuring
deletion policy, Defining a Log File Deletion Policy
disabling time stamps, Disabling High-resolution Log Time Stamps
rotation policy, Defining a Log File Rotation Policy
defined, Viewing Logs
manually rotating, Manual Log File Rotation
viewing, Displaying Log Files
viewing in command line, Viewing Logs in the Command Line
viewing in Console, Viewing the Logs through the Console
access settings
for Administration Server, Changing the Admin User's Name and Password
account inactivation, Manually Inactivating Users and Roles
from command line, Inactivating and Activating Users and Roles Using the Command Line
from console, Activating and Inactivating Users and Roles Using the Console
PAM pass-through authentication, Setting PAM PTA Mappings
account lockout, Configuring the Account Lockout Policy Using the Console
configuration
attributes, Configuring the Account Lockout Policy Using the Command Line
configuring
using command line, Configuring the Account Lockout Policy Using the Command Line
using console, Configuring the Account Lockout Policy Using the Console
configuring password-based, Configuring a Password-Based Account Lockout Policy
configuring time-based, Configuring Time-Based Account Lockout Policies
disabling, Configuring the Account Lockout Policy Using the Console
enabling, Configuring the Account Lockout Policy Using the Console
lockout duration, Configuring the Account Lockout Policy Using the Console
password failure counter, Configuring the Account Lockout Policy Using the Console
replicating attributes, Replicating Account Lockout Attributes
replication, Managing the Account Lockouts and Replication
account policy
configuring, Configuring Time-Based Account Lockout Policies
ACI
and directory manager, Setting Access Controls on Directory Manager
cascading chaining, Configuring Cascading Chaining from the Command Line
local evaluation
cascading chaining, Configuring Cascading Chaining from the Command Line
using macro ACIs, Advanced Access Control: Using Macro ACIs
ACL, Access Control Principles
activating accounts
from command line, Inactivating and Activating Users and Roles Using the Command Line
from console, Activating and Inactivating Users and Roles Using the Console
Active Directory
schema differences between Directory Server, User Schema Differences between Red Hat Directory Server and Active Directory, Group Schema Differences between Red Hat Directory Server and Active Directory
AD DN Plug-in, Using Active Directory-formatted User Names for Authentication
admin domain
creating, Creating and Editing an Admin Domain
Admin Express
configuring, Configuring Admin Express
directives, Admin Express Directives
file locations, Admin Express File Locations
files, Admin Express Configuration Files
for replication status, Files for the Replication Status Appearance
for server information page, Files for the Server Information Page
for the server logs page, Files for the Server Logs Page
for the welcome page, Files for the Administration Server Welcome Page
opening, Opening Admin Express
replication monitoring, Monitoring Replication from Admin Express
starting and stopping servers, Starting and Stopping Servers
viewing server information, Viewing Server Information
viewing server logs, Viewing Server Logs
administration domain
defined, The Servers and Applications Tab
removing, Removing an Admin Domain
Administration Server
defined, Overview of the Directory Server Console
Administration Server Administrator
changing user name or password for, Changing the Admin Password
defined, Changing the Admin User's Name and Password, Changing Administrator Entries
Administration Server
access settings for, Changing the Admin User's Name and Password
and replication, Replicating o=NetscapeRoot for Administration Server Failover
defined, Introduction to Red Hat Administration Server
directory settings for, Changing Directory Server Settings
enabling TLS, Enabling TLS
encryption settings for, Working with TLS
logging options for, Viewing Logs
login, Opening the Administration Server Console
password file, Creating a Password File for the Administration Server
port number, Changing the Port Number
in the command line, Changing the Port Number in the Command Line
in the Console, Changing the Port Number in the Console
removing, Removing a Directory Server Instance and Administration Server
requesting a certificate, Managing Certificates for Administration Server
starting and stopping, Starting and Stopping the Directory Server Administration Server Service
starting and stopping servers, Starting and Stopping Servers
starting the Console, Opening the Administration Server Console
viewing logs, Viewing Server Logs
viewing server information, Viewing Server Information
Administration Server Console
starting, Opening the Administration Server Console
administrators
changing user name, Changing the Admin User's Name and Password
resetting passwords, Changing the Admin User's Name and Password
administrators, overview of, Changing Administrator Entries
algorithm
metaphone phonetic algorithm, Approximate Searches
search, Overview of the Searching Algorithm
anonymous binds
disabling, Disabling Anonymous Binds
resource limits, Setting Resource Limits on Anonymous Binds
approximate index, About Index Types
query string codes, Approximate Searches
approximate search, Using Operators in Search Filters
attribute
adding multiple values, Adding Attribute Values
adding to entry, Adding an Attribute to an Entry
creating, Creating Attributes
defining in schema, Creating Attributes, Creating Custom Schema Files
deleting, Deleting Schema
editing, Editing Custom Schema Elements
nsslapd-schemacheck, Turning Schema Checking On and Off Using the Command Line
ref, Creating Smart Referrals from the Command Line
removing a value, Adding Attribute Values
searching for, Using Attributes in Search Filters
standard, Overview of Schema
very large, Adding Very Large Attributes
viewing, Viewing Attributes and Object Classes
attribute encryption, Configuring Attribute Encryption
importing and exporting encrypted databases, Exporting and Importing an Encrypted Database
attribute subtypes, Adding an Attribute Subtype
adding, Adding an Attribute Subtype
binary, Adding an Attribute Subtype
language, Adding an Attribute Subtype
pronunciation, Adding an Attribute Subtype
attribute type field (LDIF), About the LDIF File Format
attribute uniqueness plug-in, Enforcing Attribute Uniqueness
uniqueness-subtree-entries-oc, Configuring Attribute Uniqueness over Object Classes
uniqueness-top-entry-oc, Configuring Attribute Uniqueness over Object Classes
attribute value field (LDIF), About the LDIF File Format
attributes
allowed, Object Classes
defined, Attributes
linked attributes, Linking Attributes to Manage Attribute Values
about, About Linking Attributes
creating instance, Configuring Attribute Links
syntax, Looking at the Linking Attributes Plug-in Syntax
linking
fixup-linkedattrs.pl, Regenerating Linked Attributes Using fixup-linkedattrs.pl
managing, Managing Attributes and Values
required, Object Classes
syntax, Directory Server Attribute Syntaxes
unique number assignments, Assigning and Managing Unique Numeric Attribute Values
configuring, Configuring Unique Number Assignments, Editing the DNA Plug-in in the Console
magic number, Ranges and Assigning Numbers
overview, Assigning and Managing Unique Numeric Attribute Values
syntax, Looking at the DNA Plug-in Syntax
usage, Ranges and Assigning Numbers
audit fail log
configuring
deletion policy, Defining a Log File Deletion Policy
disabling time stamps, Disabling High-resolution Log Time Stamps
rotation policy, Defining a Log File Rotation Policy
viewing, Displaying Log Files
audit log
configuring
deletion policy, Defining a Log File Deletion Policy
disabling time stamps, Disabling High-resolution Log Time Stamps
rotation policy, Defining a Log File Rotation Policy
disabling, Enabling or Disabling Logs
enabling, Enabling or Disabling Logs
viewing, Displaying Log Files
authentication, Opening the Administration Server Console
autobind
configuring, Configuring Autobind
overview, Overview of Autobind and LDAPI
certificate-based, Using Certificate-based Client Authentication
for database links, Using Different Bind Mechanisms
LDAP URLs, Examples of LDAP URLs
SASL, Setting up SASL Identity Mapping
SASL mechanisms, Authentication Mechanisms for SASL in Directory Server
using PAM, Using PAM for Pass-Through Authentication
autobind
configuring, Configuring Autobind
overview, Overview of Autobind and LDAPI

C

cascading chaining
client ACIs, Configuring Cascading Chaining from the Command Line
configuration attributes, Summary of Cascading Chaining Configuration Attributes
configuring from command line, Configuring Cascading Chaining from the Command Line
configuring from console, Configuring Cascading Chaining Using the Console
example, Cascading Chaining Configuration Example
local ACI evaluation, Configuring Cascading Chaining from the Command Line
loop detection, Detecting Loops
overview, Overview of Cascading Chaining
proxy admin user ACI, Configuring Cascading Chaining from the Command Line
proxy authorization, Configuring Cascading Chaining from the Command Line
cascading replication
initializing the replicas, Setting up the Replication Agreements
introduction, Cascading Replication
setting up, Configuring Cascading Replication
certificate group, Groups
certificate-based authentication, Using Certificate-based Client Authentication
certificates, Managing Certificates for Administration Server
chaining
cascading, Overview of Cascading Chaining
component operations, from command line, Chaining Component Operations from the Command Line
component operations, from console, Chaining Component Operations Using the Console
overview, Creating and Maintaining Database Links
using TLS, Creating a New Database Link Using the Console, Providing an LDAP URL
changelog, Changelog
deleting, Removing the Changelog
trimming, Trimming the Replication Changelog
character type, About Locales
ciphers, Setting Encryption Ciphers
overview, Setting Encryption Ciphers
selecting, Setting Encryption Ciphers
cl-dump.pl script, Troubleshooting Replication-Related Problems
class of service (CoS), Assigning Class of Service
access control, Access Control and CoS
classic
example, How a Classic CoS Works
overview, How a Classic CoS Works
cosPriority attribute, Handling Multi-valued Attributes with CoS
creating, Creating a New CoS
definition entry, Creating the CoS Definition Entry from the Command Line
editing, Creating the CoS Template Entry
indirect
example, How an Indirect CoS Works
overview, How an Indirect CoS Works
pointer
example, How a Pointer CoS Works
overview, How a Pointer CoS Works
qualifiers
merge-scheme, Handling Multi-valued Attributes with CoS
override, Handling Physical Attribute Values
template entry
creating, Creating the CoS Template Entry
overview, About the CoS Template Entry
classic CoS
example, How a Classic CoS Works
overview, How a Classic CoS Works
client
using to find entries, Finding Directory Entries
cn=fixup linked attributes task, Regenerating Linked Attributes Using ldapmodify
cn=memberof task, Initializing and Regenerating memberOf Attributes Using ldapmodify
cn=schema reload task, Reloading Schema Using ldapmodify
cn=task
cn=schema reload task, Reloading Schema Using ldapmodify
cn=tasks
cn=backup, Backing up the Database through the cn=tasks Entry
cn=export, Manually Creating an Export Task
cn=fixup linked attributes, Regenerating Linked Attributes Using ldapmodify
cn=import, Importing through the cn=tasks Entry
cn=memberof task, Initializing and Regenerating memberOf Attributes Using ldapmodify
cn=restore, Restoring the Database through the cn=tasks Entry
creating browsing indexes, Using a cn=tasks Entry to Create a Browsing Index
creating indexes, Using a cn=tasks Entry to Create an Index
code page, About Locales
collation order
international index, Creating Indexes from the Server Console
overview, About Locales
search filters and, Searching an Internationalized Directory
command-line scripts
db2bak, Backing up All Databases from the Command Line
db2bak.pl, Backing up All Databases from the Command Line
fixup-linkedattrs.pl, Regenerating Linked Attributes Using fixup-linkedattrs.pl
fixup-memberof.pl, Initializing and Regenerating memberOf Attributes Using fixup-memberof.pl
schema-reload.pl, Reloading Schema Using schema-reload.pl
command-line utilities
certificate-based authentication and, Using Certificate-based Client Authentication
ldapsearch, LDAP Search Filters
ldif, Base-64 Encoding
ldif2db, Running the db2index.pl Script
commas, in DNs
using ldapsearch with, Specifying DNs That Contain Commas in Search Filters
compatibility
ACIs, Compatibility with Previous Releases
compound search filters, Using Compound Search Filters
Configuration Administrator
changing user name or password for, Changing Administrator Entries
defined, Changing the Admin User's Name and Password, Changing Administrator Entries
Configuration Administrators group
adding users to, Adding Users to the Configuration Administrators Group
configuration attributes
account lockout, Configuring the Account Lockout Policy Using the Command Line
cascading chaining, Summary of Cascading Chaining Configuration Attributes
password policy, Configuring a Global Password Policy Using the Command Line
configuration directory
changing settings for, Changing the Configuration Directory Host or Port
defined, Overview of the Directory Server Console
overview, Changing the Configuration Directory Host or Port
connection restrictions, Setting Host Restrictions
setting in the command line, Setting Host Restrictions in the Command Line
setting in the Console, Setting Host Restrictions in the Console
connections
LDAPI (Unix sockets), Overview of Autobind and LDAPI
configuring, Enabling LDAPI
monitoring, Monitoring the Server from the Directory Server Console
requiring secure, Requiring Secure Connections
viewing number of, Monitoring the Server from the Directory Server Console
consumer server, Suppliers and Consumers
continued lines
in LDIF, Continuing Lines in LDIF
CoS (class of service), Assigning Class of Service
CoS definition entry
attributes, Creating the CoS Definition Entry from the Command Line
object classes, Creating the CoS Definition Entry from the Command Line
CoS qualifiers
default, Handling Physical Attribute Values
merge-scheme, Handling Multi-valued Attributes with CoS
override, Handling Physical Attribute Values
CoS template entry, About the CoS Template Entry
creating, Creating the CoS Template Entry
cosPriority attribute, Handling Multi-valued Attributes with CoS
counter, password failures, Configuring the Account Lockout Policy Using the Console
country code, Supported Locales
creating a database
from the command line, Creating a New Database for a Single Suffix from the Command Line
from the console, Creating a New Database for an Existing Suffix Using the Console
creating a virtual DIT, About Views
creating the directory, Defining Directories Using LDIF
custom distribution function
adding to suffix, Adding Multiple Databases for a Single Suffix
custom distribution logic
adding databases, Adding Multiple Databases for a Single Suffix
adding to suffix, Adding Multiple Databases for a Single Suffix
custom schema files, Creating Custom Schema Files
custom views, Changing the Console Appearance
changing to, Switching to a Custom View
creating, Creating Custom Views
editing, Creating Custom Views
removing, Creating Custom Views
setting ACIs on, Setting Access Permissions for a Public View
using, Working with Custom Views

D

data consistency
using referential integrity, Maintaining Referential Integrity
database
and associated suffix, Creating and Maintaining Suffixes
backing up
cn=tasks, Backing up the Database through the cn=tasks Entry
db2bak, Backing up All Databases from the Command Line
db2bak.pl, Backing up All Databases from the Command Line
backup, Backing up and Restoring Data
backup files, Backing up All Databases from the Console
backup from console, Backing up All Databases
creating from command line, Creating a New Database for a Single Suffix from the Command Line
creating from console, Creating a New Database for an Existing Suffix Using the Console
creating multiple, Adding Multiple Databases for a Single Suffix
creating using LDIF, Defining Directories Using LDIF
deleting, Deleting a Database
export, Exporting Data
cn=tasks, Manually Creating an Export Task
db2ldif, Exporting a Database Using the db2ldif.pl Script
db2ldif.pl, Exporting a Database Using the db2ldif.pl Script
encrypted database, Exporting and Importing an Encrypted Database
export from console, Exporting Directory Data to LDIF Using the Console
import, Importing Data
cn=tasks, Importing through the cn=tasks Entry
encrypted database, Exporting and Importing an Encrypted Database
ldif2db, Importing Using the ldif2db Command-Line Script
ldif2db.pl, Importing Using the ldif2db.pl Perl Script
ldif2ldap, Importing Using the ldif2ldap Command-Line Script
initialization, Initializing a Database from the Console
making read-only, Placing a Database in Read-Only Mode
monitoring from command line, Monitoring Databases from the Command Line
monitoring from server console, Monitoring Database Activity from the Directory Server Console
overview, Creating and Maintaining Databases
read-only mode, Placing a Database in Read-Only Mode
replication, What Directory Units Are Replicated
restore, Backing up and Restoring Data
restoring
bak2db, Using the bak2db Command-Line Script
bak2db.pl, Using bak2db.pl Perl Script
cn=tasks, Restoring the Database through the cn=tasks Entry
restoring from console, Restoring All Databases from the Console
selecting for monitoring, Monitoring Database Activity
viewing backend information, Monitoring Database Activity
database link
cascading
configuring from command line, Configuring Cascading Chaining from the Command Line
configuring from console, Configuring Cascading Chaining Using the Console
overview, Overview of Cascading Chaining
chaining with TLS, Creating a New Database Link Using the Console, Providing an LDAP URL
configuration, Creating a New Database Link
configuration attributes, Summary of Database Link Configuration Attributes
configuration example, Summary of Database Link Configuration Attributes
configuring bind and authentication, Using Different Bind Mechanisms
configuring bind credentials, Providing Bind Credentials
configuring defaults, Configuring Database Link Defaults
configuring failover servers, Providing a List of Failover Servers
configuring LDAP URL, Providing an LDAP URL
configuring suffix, Creating a Database Link from the Command Line
creating from command line, Creating a Database Link from the Command Line
creating from console, Creating a New Database Link Using the Console
deleting, Deleting Database Links
maintaining remote server info, Maintaining Database Links
overview, Creating and Maintaining Database Links
database server parameters
read-only, Monitoring Database Activity from the Directory Server Console
databases
in Directory Server, Configuring Directory Databases
date format, About Locales
db2bak script, Backing up All Databases from the Command Line
db2bak utility, Backing up All Databases from the Command Line
db2bak.pl script, Backing up All Databases from the Command Line
db2ldif utility, Exporting a Database Using the db2ldif.pl Script
db2ldif.pl, Exporting a Database Using the db2ldif.pl Script
debug
and replication timeouts, Setting Replication Timeout Periods
default CoS qualifier, Handling Physical Attribute Values
default referrals
setting, Setting Default Referrals
setting from console, Setting a Default Referral Using the Console
settings from command line, Setting a Default Referral from the Command Line
defining
attributes, Creating Attributes
object classes, Creating Object Classes
deleting
attributes, Deleting Schema
database link, Deleting Database Links
object classes, Deleting Schema
deleting schema elements, Deleting Schema
directives, Admin Express Directives
directory
changing the search directory, Searching for Users and Groups
directory creation, Defining Directories Using LDIF
directory entries
creating, Creating Directory Entries, Creating Directory Entries
deleting, Deleting Directory Entries
managing from console, Managing Entries Using the Directory Console
modifying, Modifying Directory Entries
removing, Removing an Entry from the Directory
searching for, Searching for Users and Groups
directory manager
and access control, Setting Access Controls on Directory Manager
Directory Manager
password, Managing the Directory Manager Password, Resetting the Directory Manager Password
directory trees
finding entries in, Using ldapsearch
Directory Server
basic administration, Basic Red Hat Directory Server Settings, Setting up Content Synchronization
configuration, Changing Directory Server Port Numbers
configuration subtree, Overview of the Directory Server Console
configuring SASL authentication at startup, Configuring SASL Authentication at Directory Server Startup
connecting over LDAPI (Unix sockets), Overview of Autobind and LDAPI
creating a root entry, Creating a Root Entry
creating content, Populating Directory Databases
creating entries, Creating Directory Entries
data, Populating Directory Databases
databases, Configuring Directory Databases
deleting entries, Deleting Directory Entries
file locations, File Locations
importing data, Importing Data
international charactersets, Internationalization
managing attributes, Managing Attributes and Values
managing entries, Managing Directory Entries
MIB, Using the Management Information Base
modifying entries, Modifying Directory Entries
monitoring, Types of Directory Server Log Files
monitoring from command line, Monitoring the Directory Server from the Command Line
monitoring with SNMP, Monitoring Directory Server Using SNMP
overview, Basic Red Hat Directory Server Settings
performance counters, Monitoring Server Activity, Enabling and Disabling Counters
64-bit, Monitoring Server Activity, Monitoring Database Activity, Using the Management Information Base
reloading schema, Dynamically Reloading Schema
cn=schema reload task, Reloading Schema Using ldapmodify
schema-reload.pl, Reloading Schema Using schema-reload.pl
removing a single instance, Removing a Directory Server Instance Using the Command Line
removing Directory Server and Administration Server, Removing a Directory Server Instance and Administration Server
removing instance, Removing a Directory Server Instance Using the Console
replication monitoring, Monitoring Replication from Admin Express
role in managing resources and users, Overview of the Directory Server Console
starting and stopping, Starting and Stopping a Directory Server Instance Using the Command Line
starting and stopping servers, Starting and Stopping Servers
suffixes, Configuring Directory Databases
supported languages, Supported Locales
user subtree, Overview of the Directory Server Console
viewing information, Viewing Server Information
viewing logs, Viewing Server Logs
Directory Server Console
managing certificates, Managing Certificates Used by the Directory Server Console
disabling suffixes, Disabling a Suffix
disk space
access log and, Enabling or Disabling Logs
log files and, Manual Log File Rotation
distributed number assignment, Assigning and Managing Unique Numeric Attribute Values
about ranges, About Dynamic Number Assignments
basic example, Looking at the DNA Plug-in Syntax
complete example, Looking at the DNA Plug-in Syntax
configuring, Configuring Unique Number Assignments, Editing the DNA Plug-in in the Console
Directory Server behavior, Assigning and Managing Unique Numeric Attribute Values
for attributes, Ranges and Assigning Numbers
overview, Assigning and Managing Unique Numeric Attribute Values
scope, Filters, Searches, and Target Entries
syntax, Looking at the DNA Plug-in Syntax
distribution function, Adding Multiple Databases for a Single Suffix
dn field (LDIF), About the LDIF File Format
DNs
validating syntax, Enabling Strict Syntax Validation for DNs
dse.ldif file
backing up, Backing up the dse.ldif Configuration File
restoring, Restoring the dse.ldif Configuration File
dynamic group, Groups
dynamic groups, Creating Dynamic Groups in the Console
creating, Creating Dynamic Groups in the Console
modifying, Creating Dynamic Groups in the Console

E

editing
attributes, Editing Custom Schema Elements
object classes, Editing Custom Schema Elements
encryption
attribute, Configuring Attribute Encryption
database, Configuring Attribute Encryption
settings for Administration Server, Working with TLS
entity table, Entity Table
entries
adding an object class, Adding or Removing an Object Class to an Entry
adding attributes, Adding an Attribute to an Entry
adding very large attributes, Adding Very Large Attributes
creating, Creating Directory Entries
using LDIF, Specifying Directory Entries Using LDIF
deleting, Deleting Directory Entries
deleting and replication, Managing Deleted Entries with Replication
distribution, Creating Databases
finding, Using ldapsearch
managing, Managing Directory Entries
managing from console, Managing Entries Using the Directory Console
modifying, Modifying Directory Entries
removing an object class, Adding or Removing an Object Class to an Entry
root, Defining Directories Using LDIF
entry distribution, Creating Databases
entryUSN
import operations, Setting EntryUSN Initial Values During Import
initializing replicas and databases, Setting EntryUSN Initial Values During Import
entryUSN:
import operations, Setting EntryUSN Initial Values During Import
environment variables
LDAP_BASEDN, Using LDAP_BASEDN
equality index, About Index Types
required for referential integrity, How Referential Integrity Works
equality search, Using Operators in Search Filters
example, Using Attributes in Search Filters
international example, Equality Example
error log
access control information, Logging Access Control Information
changing location and name
in the command line, Changing the Log Location in the Command Line
in the Console, Changing the Log Name in the Console
configuring
deletion policy, Defining a Log File Deletion Policy
disabling time stamps, Disabling High-resolution Log Time Stamps
rotation policy, Defining a Log File Rotation Policy
defined, Viewing Logs
manually rotating, Manual Log File Rotation
viewing, Displaying Log Files
viewing in command line, Viewing Logs in the Command Line
viewing in Console, Viewing the Logs through the Console
example
cascading chaining, Cascading Chaining Configuration Example
exporting data, Exporting Data
cn=tasks, Manually Creating an Export Task
db2ldif, Exporting a Database Using the db2ldif.pl Script
db2ldif.pl, Exporting a Database Using the db2ldif.pl Script
encrypted database, Exporting and Importing an Encrypted Database
using console, Exporting Directory Data to LDIF Using the Console
extending the directory schema, Managing the Directory Schema

I

id field (LDIF), About the LDIF File Format
identity mapping
default, Default SASL Mappings for Directory Server
importing data, Importing Data
cn=tasks, Importing through the cn=tasks Entry
encrypted database, Exporting and Importing an Encrypted Database
from console, Importing a Database from the Console
ldif2ldap, Importing Using the ldif2ldap Command-Line Script
using ldif2db, Importing Using the ldif2db Command-Line Script
using ldif2db.pl, Importing Using the ldif2db.pl Perl Script
inactivating accounts, Manually Inactivating Users and Roles
inactivating roles, Making a Role Inactive or Active
index types, About Index Types
approximate index, About Index Types
browsing index, About Index Types
equality index, About Index Types
international index, About Index Types
presence index, About Index Types
substring index, About Index Types
virtual list view index, About Index Types
indexes
creating
cn=tasks, Using a cn=tasks Entry to Create an Index
creating dynamically, Creating Indexes from the Command Line
dynamic changes to, Creating Indexes from the Command Line
matching rules, Using Matching Rules
required for referential integrity, How Referential Integrity Works
indexing, About Index Types
creating indexes from console, Creating Indexes from the Server Console
indirect CoS
example, How an Indirect CoS Works
overview, How an Indirect CoS Works
init scripts
configuring SASL authentication, Configuring SASL Authentication at Directory Server Startup
initialization
and entryUSN values, Setting EntryUSN Initial Values During Import
and suppliers in MMR, Setting EntryUSN Initial Values During Import
manual consumer creation, Manual Consumer Initialization Using the Command Line
online consumer creation, Online Consumer Initialization Using the Console
initializing databases, Initializing a Database from the Console
initializing replicas
cascading replication, Setting up the Replication Agreements
interaction table, Interaction Table
international charactersets, Internationalization
international index, About Index Types
collation order, Creating Indexes from the Server Console
international searches, Searching an Internationalized Directory
equality, Equality Example
examples, International Search Examples
greater than, Greater-Than Example
greater than or equal to, Greater-Than or Equal-to Example
less than, Less-Than Example
less than or equal to, Less-Than or Equal-to Example
substring, Substring Example
using OIDs, Matching Rule Formats
internationalization
character type, About Locales
collation order, About Locales
country code, Supported Locales
date format, About Locales
language tag, Supported Locales
locales and, About Locales
location of files, About Locales
monetary format, About Locales
object identifiers and, Supported Locales
of LDIF files, Storing Information in Multiple Languages
search filters and, Searching an Internationalized Directory
supported locales, Supported Locales
time format, About Locales

L

language code
in LDIF entries, Storing Information in Multiple Languages
list of supported, Supported Locales
language subtype, Adding an Attribute Subtype
language support
language tag, Supported Locales
searching and, Searching an Internationalized Directory
specifying using locales, Supported Locales
language tags
described, Supported Locales
in international searches, Using a Language Tag for the Matching Rule
LDAP clients
certificate-based authentication and, Using Certificate-based Client Authentication
monitoring database with, Monitoring Databases from the Command Line
monitoring server with, Monitoring the Directory Server from the Command Line
using to find entries, Finding Directory Entries
LDAP search filters
DNs with commas and, Specifying DNs That Contain Commas in Search Filters
LDAP URLs
components of, Components of an LDAP URL
examples, Examples of LDAP URLs
for database links, Providing an LDAP URL
security, Examples of LDAP URLs
syntax, Components of an LDAP URL
ldapcompare command-line utility
examples, Comparing Entries
LDAPI
enabling, Enabling LDAPI
overview, Overview of Autobind and LDAPI
ldappasswd command-line utility
changing user password, Changing Passwords
generating user password, Changing Passwords
prompting for new password, Changing Passwords
ldapsearch command-line utility
extended operations, Running Extended Operations
ldapsearch utility
base DN and, Using LDAP_BASEDN
commonly used options, Commonly Used ldapsearch Options
DNs with commas and, Using Special Characters
example of use, Examples of Common ldapsearches
format, ldapsearch Command-Line Format
international searches, Searching an Internationalized Directory
limiting attributes returned, Displaying Subsets of Attributes
search filters, LDAP Search Filters
specifying files, Displaying Subsets of Attributes
using, Using ldapsearch
LDAP_BASEDN environment variable, Using LDAP_BASEDN
LDIF
binary data, Representing Binary Data
entry format, LDAP Data Interchange Format
organization, Specifying Domain Entries
organizational person, Specifying Organizational Person Entries
organizational unit, Specifying Organizational Unit Entries
example, Defining Directories Using LDIF
internationalization and, Storing Information in Multiple Languages
line continuation, Continuing Lines in LDIF
specifying entries
organization, Specifying Domain Entries
organizational person, Specifying Organizational Person Entries
organizational unit, Specifying Organizational Unit Entries
using to create directory, Defining Directories Using LDIF
LDIF entries
binary data in, Representing Binary Data
creating, Specifying Directory Entries Using LDIF
organizational person, Specifying Organizational Person Entries
organizational units, Specifying Organizational Unit Entries
organizations, Specifying Domain Entries
internationalization and, Storing Information in Multiple Languages
LDIF files
continued lines, Continuing Lines in LDIF
creating directory using, Defining Directories Using LDIF
example, Defining Directories Using LDIF
internationalization and, Storing Information in Multiple Languages
LDIF format, LDAP Data Interchange Format
ldif utility
converting binary data to LDIF, Base-64 Encoding
ldif2db utility, Importing Using the ldif2db Command-Line Script
options, Running the db2index.pl Script
ldif2db.pl perl script, Importing Using the ldif2db.pl Perl Script
ldif2ldap utility, Importing Using the ldif2ldap Command-Line Script
less than or equal to search
international example, Less-Than or Equal-to Example
syntax, Using Operators in Search Filters
less than search
international example, Less-Than Example
syntax, Using Operators in Search Filters
linked attributes, Linking Attributes to Manage Attribute Values
about, About Linking Attributes
and replication, About Linking Attributes
attribute requirements, About Linking Attributes
creating, Configuring Attribute Links
data consistency and ACIs, About Linking Attributes
scope, About Linking Attributes
syntax, Looking at the Linking Attributes Plug-in Syntax
local password policy, Configuring a Local Password Policy
locales
defined, About Locales
location of files, About Locales
supported, Supported Locales
locked accounts, Configuring the Account Lockout Policy Using the Console
lockout duration, Configuring the Account Lockout Policy Using the Console
log files, Types of Directory Server Log Files
access log, Types of Directory Server Log Files
audit fail log, Types of Directory Server Log Files
audit log, Types of Directory Server Log Files
deletion policy, Defining a Log File Deletion Policy
disabling time stamps, Disabling High-resolution Log Time Stamps
error log, Types of Directory Server Log Files
location of, Manual Log File Rotation
manually rotating, Manual Log File Rotation
rotation policy, Defining a Log File Rotation Policy
viewing, Displaying Log Files
logging
for Windows Synchronization, Troubleshooting
logs
changing location and name
in the command line, Changing the Log Location in the Command Line
in the Console, Changing the Log Name in the Console
transaction
moving, Changing the Transaction Log Directory
viewing access, Viewing the Logs through the Console, Viewing Logs in the Command Line
viewing error, Viewing the Logs through the Console, Viewing Logs in the Command Line
loop detection
cascading chaining, Detecting Loops

M

macro ACIs
example, Macro ACI Example
overview, Advanced Access Control: Using Macro ACIs
syntax, Macro ACI Syntax
managed device
overview, About SNMP
managed object, About SNMP
managed role
creating, Creating a Managed Role
example, Creating Managed Roles through the Command Line
manually rotating log files, Manual Log File Rotation
matching rules, Using Matching Rules
international formats, Matching Rule Formats
list of supported, Using Matching Rules
matchingRule format
using language tag, Using a Language Tag for the Matching Rule
using language tag and suffix, Using a Language Tag and Suffix for the Matching Rule
using OID, Matching Rule Formats
using OID and suffix, Using an OID and Suffix for the Matching Rule
memberOf plug-in
configuring, Configuring an Instance of the MemberOf Plug-in
from the command line, Editing the MemberOf Plug-in from the Command Line
from the console, Editing the MemberOf Plug-in from the Console
menus, in Red Hat Management Console, Red Hat Management Console Menus
metaphone phonetic algorithm, Approximate Searches
MIB
Directory Server, Using the Management Information Base
redhat-directory.mib, Using the Management Information Base
entity table, Entity Table
entries table, Entries Table
interaction table, Interaction Table
operations table, Operations Table
monetary format, About Locales
monitoring
database from command line, Monitoring Databases from the Command Line
database from server console, Monitoring Database Activity from the Directory Server Console
Directory Server, Types of Directory Server Log Files
from console, Monitoring Server Activity
log files, Types of Directory Server Log Files
replication status, Monitoring Replication Status
threads, Monitoring the Server from the Directory Server Console
with SNMP, Monitoring Directory Server Using SNMP
monitoring from console, Monitoring Server Activity
multi-master replication
introduction, Multi-Master Replication
preventing monopolization of a consumer, Preventing Monopolization of a Consumer in Multi-Master Replication
setting up, Configuring Multi-Master Replication
multiple search filters, Using Compound Search Filters

O

object class
adding to an entry, Adding or Removing an Object Class to an Entry
allowed attributes, Object Classes
creating, Creating Object Classes
defined, Object Classes
defining in schema, Creating Object Classes, Creating Custom Schema Files
deleting, Deleting Schema
editing, Editing Custom Schema Elements
inheritance, Object Classes
parent object class, Object Classes
referral, Creating Smart Referrals from the Command Line
removing from an entry, Adding or Removing an Object Class to an Entry
required attributes, Object Classes
standard, Overview of Schema
user-defined, Viewing Attributes and Object Classes
viewing, Viewing Attributes and Object Classes
object identifier, Managing Object Identifiers
object identifier (OID), Supported Locales
in matchingRule, Matching Rule Formats
matching rule, Using Matching Rules
objectClass field (LDIF), About the LDIF File Format
OID
getting and assigning, Managing Object Identifiers
OID, See object identifier, Supported Locales
operations, Monitoring the Server from the Directory Server Console
operations table, Operations Table
operators
Boolean, Using Compound Search Filters
international searches and, Supported Search Types
search filters and, Using Operators in Search Filters
suffix, Supported Search Types
organization, specifying entries for, Specifying Domain Entries
organizational person, specifying entries for, Specifying Organizational Person Entries
organizational unit, specifying entries for, Specifying Organizational Unit Entries
organizational units
creating, Organizational Units
removing, Removing an Entry from the Directory
override CoS qualifier, Handling Physical Attribute Values

P

PAM pass-through authentication, Using PAM for Pass-Through Authentication
and account inactivation, Setting PAM PTA Mappings
and password policies, Using PAM for Pass-Through Authentication
configuration options, PAM Pass-Through Authentication Configuration Options
configuring, Configuring PAM Pass-Through Authentication
entry mapping methods, Setting PAM PTA Mappings
example, Configuring PAM Pass-Through Authentication
general settings, Configuring General PAM PTA Settings
target suffixes, Specifying the Suffixes to Target for PAM PTA
parent object class, Object Classes
pass-through authentication
PAM, Using PAM for Pass-Through Authentication
pass-through authentication (PTA), Using Pass-Through Authentication
password
changing for a user or administrator, Editing Entries
password change extended operation, Changing Passwords Stored Externally
password file
Administration Server, Creating a Password File for the Administration Server
password policy
account lockout, Configuring the Account Lockout Policy Using the Console
attributes, Configuring a Global Password Policy Using the Command Line
configuring
using command line, Configuring a Global Password Policy Using the Command Line
using console, Configuring a Global Password Policy Using the Console
configuring global, Configuring the Global Password Policy
configuring local, Configuring a Local Password Policy
global, Configuring the Global Password Policy
lockout duration, Configuring the Account Lockout Policy Using the Console
managing, Managing the Password Policy
password failure counter, Configuring the Account Lockout Policy Using the Console
replicating account lockout attributes, Replicating Account Lockout Attributes
replication, Managing the Account Lockouts and Replication
subtree-level, Configuring a Local Password Policy
user-level, Configuring a Local Password Policy
Password Sync, Managing the Password Sync Service
modifying, Modifying Password Sync
setting up TLS, Step 5: Configure the Password Sync Service
starting and stopping, Starting and Stopping the Password Sync Service
uninstalling, Uninstalling Password Sync Service
passwords, Changing the Admin User's Name and Password
account lockout, Configuring the Account Lockout Policy Using the Console
changing, Changing Passwords Stored Externally
Directory Manager, Resetting the Directory Manager Password
failure counter, Configuring the Account Lockout Policy Using the Console
lockout duration, Configuring the Account Lockout Policy Using the Console
policy
differences between Directory Server and Active Directory, Password Policies
setting, Setting User Passwords
synchronizing, Synchronizing Passwords
syncing with Active Directory, Managing the Password Sync Service
PDUs, About SNMP
performance counters, Monitoring Database Activity from the Directory Server Console
configuring 64-bit, Monitoring Server Activity, Monitoring Database Activity, Using the Management Information Base
configuring 64-bit integers, Enabling and Disabling Counters
monitoring the server with, Monitoring Server Activity
server attributes, Enabling and Disabling Counters
PKCS#11 modules, Using Hardware Security Modules
plug-ins
directory manager ACI, Setting Access Controls on Directory Manager
disabling, Enabling Plug-ins in the Command Line, Enabling Plug-ins in the Directory Server Console
displaying details in the Console, Enabling Plug-ins in the Directory Server Console
distributed number assignment, Assigning and Managing Unique Numeric Attribute Values
configuring, Configuring Unique Number Assignments, Editing the DNA Plug-in in the Console
overview, Assigning and Managing Unique Numeric Attribute Values
syntax, Looking at the DNA Plug-in Syntax
dynamic plug-ins, Enabling Plug-ins Dynamically
enabling, Enabling Plug-ins in the Command Line, Enabling Plug-ins in the Directory Server Console
linked attributes, Linking Attributes to Manage Attribute Values
about, About Linking Attributes
creating instance, Configuring Attribute Links
scope, About Linking Attributes
syntax, Looking at the Linking Attributes Plug-in Syntax
setting precedence, Setting the Plug-in Precedence
pointer CoS
example, How a Pointer CoS Works
overview, How a Pointer CoS Works
port number, Changing Standard Port Numbers, Changing the Port Number
changing in the command line, Changing the Port Number in the Command Line
changing in the Console, Changing the Port Number in the Console
Directory Server configuration, Changing Directory Server Port Numbers
for TLS communications, Changing the LDAPS Port Numbers
preferences, Changing the Console Appearance
font, Changing Console Fonts
UI permissions, Changing the Console Appearance
presence index, About Index Types
required for referential integrity, How Referential Integrity Works
presence search
example, Using Attributes in Search Filters
syntax, Using Operators in Search Filters
preventing monopolization of the consumer in multi-master replication, Preventing Monopolization of a Consumer in Multi-Master Replication
pronunciation subtype, Adding an Attribute Subtype
Property Editor
displaying, Modifying Directory Entries
protocol data units. See PDUs, About SNMP
proxy authorization
with cascading chaining, Configuring Cascading Chaining from the Command Line
PTA plug-in
configuring, Configuring the PTA Plug-in
examples, PTA Plug-in Syntax Examples
syntax, PTA Plug-in Syntax
use in Directory Server, Using Pass-Through Authentication

R

read-only mode, Monitoring Database Activity from the Directory Server Console
database, Placing a Database in Read-Only Mode
read-only replica, Read-Write and Read-Only Replicas
read-write replica, Read-Write and Read-Only Replicas
redhat-directory.mib, Using the Management Information Base
entity table, Entity Table
entries table, Entries Table
interaction table, Interaction Table
operations table, Operations Table
Red Hat Console
overview of, Overview of the Directory Server Console
Red Hat Management Console
defined, Overview of the Directory Server Console
information panel, The Servers and Applications Tab
menus, Red Hat Management Console Menus
tabs, Red Hat Management Console Tabs
ref attribute, Creating Smart Referrals from the Command Line
refer command, Starting the Server in Referral Mode
referential integrity
attributes, How Referential Integrity Works
disabling, Enabling and Disabling Referential Integrity in the Console
enabling, Enabling and Disabling Referential Integrity in the Console
log file, How Referential Integrity Works
modifying attributes, Modifying the Attribute List Using the Console
overview, Maintaining Referential Integrity
required indexes, How Referential Integrity Works
with replication, Using Referential Integrity with Replication
referral mode, Starting the Server in Referral Mode
referral object class, Creating Smart Referrals from the Command Line
referrals
creating smart referrals, Creating Smart Referrals
creating suffix, Creating Suffix Referrals
on update, Creating Suffix Referrals Using the Console
setting default, Setting Default Referrals
suffix, Creating Suffix Referrals Using the Console
reloading schema, Dynamically Reloading Schema
cn=schema reload task, Reloading Schema Using ldapmodify
schema-reload.pl, Reloading Schema Using schema-reload.pl
removing
Directory Server instance, Removing a Directory Server Instance Using the Console
Removing Directory Server
and the Administration Server, Removing a Directory Server Instance and Administration Server
single instance, Removing a Directory Server Instance Using the Command Line
replica
exporting to LDIF, Exporting a Replica to LDIF
read-only, Read-Write and Read-Only Replicas
read-write, Read-Write and Read-Only Replicas
replication
account lockout attributes, Replicating Account Lockout Attributes
and ou=NetscapeRoot, Replicating o=NetscapeRoot for Administration Server Failover
and password policy, Managing the Account Lockouts and Replication
and referential integrity, Using Referential Integrity with Replication
and the Administration Server, Replicating o=NetscapeRoot for Administration Server Failover
and TLS, Replication over TLS
cascading, Configuring Cascading Replication
changelog, Changelog
configuring from the command line, Configuring Replication from the Command Line
configuring TLS, Replication over TLS
consumer server, Suppliers and Consumers
creating the supplier bind DN, Creating the Supplier Bind DN Entry
forcing synchronization, Forcing Replication Updates
fractional, Replicating a Subset of Attributes with Fractional Replication
hub, Suppliers and Consumers
managing, Managing Replication
monitoring status, Monitoring Replication Status
multi-master, Configuring Multi-Master Replication
overview, Replication Overview
purging RUV, Resolving Errors for Obsolete or Missing Suppliers
removing supplier and RUV, Removing a Supplier from the Replication Topology
replication manager entry, Replication Identity
single-master, Configuring Single-Master Replication
solving conflicts, Solving Common Replication Conflicts
supplier bind DN, Replication Identity
supplier server, Suppliers and Consumers
supplier-initiated, Suppliers and Consumers
suspending, Temporarily Suspending Replication
timeout periods, Setting Replication Timeout Periods
tombstone entries
purging, Managing Deleted Entries with Replication
troubleshooting, Troubleshooting Replication-Related Problems
unit of, What Directory Units Are Replicated
using cl-dump.pl script, Troubleshooting Replication-Related Problems
replication agreement, Replication Agreement
replication agreements
suspending replication, Temporarily Suspending Replication
replication manager, Replication Identity
replication monitoring, Monitoring Replication from Admin Express
resource limits
setting
for anonymous binds, Setting Resource Limits on Anonymous Binds
using command line, Setting User and Global Resource Limits Using the Command Line
using console, Setting Resource Limits on a Single User
Resource Summary
viewing, Monitoring the Server from the Directory Server Console
resource use
connections, Monitoring the Server from the Directory Server Console
monitoring, Monitoring the Server from the Directory Server Console
restoring data, Backing up and Restoring Data
bak2db, Using the bak2db Command-Line Script
bak2db.pl, Using bak2db.pl Perl Script
cn=tasks, Restoring the Database through the cn=tasks Entry
dse.ldif, Restoring the dse.ldif Configuration File
from console, Restoring All Databases from the Console
replicated entries, Restoring Databases That Include Replicated Entries
retro changelog
and access control, Retro Changelog and the Access Control Policy
attributes, Using the Retro Changelog Plug-in
object class, Using the Retro Changelog Plug-in
searching, Retro Changelog and the Access Control Policy
trimming, Trimming the Retro Changelog
retro changelog plug-in
enabling, Enabling the Retro Changelog Plug-in
roles, Using Roles
access control, Using Roles Securely
activating, Activating and Inactivating Users and Roles Using the Console
assigning, Editing and Assigning Roles to an Entry
filtered
creating, Creating a Filtered Role
example, Creating a Filtered Role through the Command Line
inactivating, Making a Role Inactive or Active
managed
creating, Creating a Managed Role
example, Creating Managed Roles through the Command Line
nested
creating, Creating a Nested Role
example, Creating Nested Role through the Command Line
overview, About Roles
root DSE, Searching the Root DSE Entry
root entry creation, Defining Directories Using LDIF
root suffix, Creating Suffixes
creating from command line, Creating Root and Sub Suffixes using the Command Line
creating from console, Creating a New Root Suffix Using the Console
RUV
purging old supplier entries, Resolving Errors for Obsolete or Missing Suppliers

S

SASL, Setting up SASL Identity Mapping
configuring
KDC server, About the KDC Server and Keytabs
configuring authentication at startup, Configuring SASL Authentication at Directory Server Startup
configuring server to server mappings, About SASL Identity Mapping
identity mapping, About SASL Identity Mapping
configuring form the Console, Configuring SASL Identity Mapping from the Console
configuring from the command line, Configuring SASL Identity Mapping from the Command Line
default, Default SASL Mappings for Directory Server
Kerberos, Using Kerberos GSS-API with SASL
Kerberos realms, About Principals and Realms
mechanisms, Authentication Mechanisms for SASL in Directory Server
CRAM-MD5, Authentication Mechanisms for SASL in Directory Server
DIGEST-MD5, Authentication Mechanisms for SASL in Directory Server
EXTERNAL, Authentication Mechanisms for SASL in Directory Server
GSS-API, Authentication Mechanisms for SASL in Directory Server
PLAIN, Authentication Mechanisms for SASL in Directory Server
overview, Setting up SASL Identity Mapping
password change extended operation, Changing Passwords Stored Externally
requiring for connections, Requiring Secure Connections
requiring secure binds, Requiring Secure Binds
using with ldapsearch, Using SASL with LDAP Clients
schema
adding new attributes, Creating Attributes, Creating Custom Schema Files
assigning OIDs, Managing Object Identifiers
checking, Turning Schema Checking On and Off
creating new attributes, Creating Attributes
creating new object classes, Creating Object Classes
custom files, Creating Custom Schema Files
deleting attributes, Deleting Schema
deleting elements, Deleting Schema
deleting object classes, Deleting Schema
differences between Directory Server and Active Directory, User Schema Differences between Red Hat Directory Server and Active Directory, Group Schema Differences between Red Hat Directory Server and Active Directory
cn, Values for cn Attributes
initials, Constraints on the initials Attribute
street and streetAddress, Values for street and streetAddress
editing attributes, Editing Custom Schema Elements
editing object classes, Editing Custom Schema Elements
extending, Managing the Directory Schema
nsslapd-schemacheck attribute, Turning Schema Checking On and Off Using the Command Line
reloading, Dynamically Reloading Schema
cn=schema reload task, Reloading Schema Using ldapmodify
schema-reload.pl, Reloading Schema Using schema-reload.pl
standard, Managing the Directory Schema
viewing attributes, Viewing Attributes and Object Classes
viewing object classes, Viewing Attributes and Object Classes
schema checking
overview, Turning Schema Checking On and Off
turning on or off, Turning Schema Checking On and Off
turning on or off in the command line, Turning Schema Checking On and Off Using the Command Line
schema-reload.pl, Reloading Schema Using schema-reload.pl
scripts
cl-dump.pl, Troubleshooting Replication-Related Problems
search filters, LDAP Search Filters
Boolean operators, Using Compound Search Filters
contained in file, Displaying Subsets of Attributes
examples, LDAP Search Filters
matching rule, Using Matching Rules
operators in, Using Operators in Search Filters
specifying attributes, Using Attributes in Search Filters
syntax, LDAP Search Filters
using compound, Using Compound Search Filters
using multiple, Using Compound Search Filters
Search Performance, Search Performance and Resource Limits
search types
list of, Using Operators in Search Filters
searches
approximate, Using Operators in Search Filters
equality, Using Operators in Search Filters
example, Examples of Common ldapsearches
greater than or equal to, Using Operators in Search Filters
international, Searching an Internationalized Directory
international examples, International Search Examples
less than, Less-Than Example
less than or equal to, Using Operators in Search Filters
of directory tree, Using ldapsearch
presence, Using Operators in Search Filters
specifying scope, Commonly Used ldapsearch Options
substring, Using Operators in Search Filters
searching
changing the search directory, Searching for Users and Groups
for directory entries, Searching for Users and Groups
searching algorithm
overview, Overview of the Searching Algorithm
security
LDAP URLs, Examples of LDAP URLs
setting encryption ciphers, Setting Encryption Ciphers
security strength factor, Requiring Secure Connections
server
defined, The Servers and Applications Tab
server group
defined, The Servers and Applications Tab
modifying information for, Editing Domain, Host, Server Group, and Instance Information
server instance
modifying information for, Editing Domain, Host, Server Group, and Instance Information
server parameters
database
read-only, Monitoring Database Activity from the Directory Server Console
setting passwords, Setting User Passwords
Simple Authentication and Security Layer, Setting up SASL Identity Mapping
simple binds
requiring secure connections, Requiring Secure Binds
Simple Network Management Protocol. See SNMP, About SNMP
single-master replication
introduction, Single-Master Replication
setting up, Configuring Single-Master Replication
smart referrals
creating, Creating Smart Referrals
creating from command line, Creating Smart Referrals from the Command Line
creating from console, Creating Smart Referrals Using the Directory Server Console
SNMP
configuring
Directory Server, Configuring the Directory Server for SNMP
managed device, About SNMP
managed objects, About SNMP
master agent, About SNMP
MIB
entity table, Entity Table
entries table, Entries Table
interaction table, Interaction Table
operations table, Operations Table
monitoring the Directory Server, Monitoring Directory Server Using SNMP
overview, About SNMP
subagent, About SNMP
SSF, Requiring Secure Connections
and SASL, Setting a Minimum Strength Factor
and StartTLS, Setting a Minimum Strength Factor
setting minimum, Setting a Minimum Strength Factor
standard
attributes, Overview of Schema
object classes, Overview of Schema
schema, Managing the Directory Schema
starting and stopping
Directory Server and Administration Server, Starting and Stopping a Directory Server Instance
Starting and stopping
Administration Server Console, Opening the Administration Server Console
starting and stopping servers, Starting and Stopping Servers
static group, Groups
static groups, Creating Static Groups in the Console
creating, Creating Static Groups in the Console
modifying, Creating Static Groups in the Console
sub suffix, Creating Suffixes
creating from command line, Creating Root and Sub Suffixes using the Command Line
creating from console, Creating a New Sub Suffix Using the Console
substring index, About Index Types
required for referential integrity, How Referential Integrity Works
substring index limitation, About Index Types
substring search, Using Operators in Search Filters
international example, Substring Example
subtree-level password policy, Configuring a Local Password Policy
subtypes
of attributes, Adding an Attribute Subtype
suffix
and associated database, Creating and Maintaining Suffixes
creating, Creating a Root Entry
creating from command line, Creating Root and Sub Suffixes using the Command Line
creating root suffix, Creating a New Root Suffix Using the Console
creating sub suffix, Creating a New Sub Suffix Using the Console
custom distribution function, Adding Multiple Databases for a Single Suffix
custom distribution logic, Adding Multiple Databases for a Single Suffix
disabling, Disabling a Suffix
in Directory Server, Configuring Directory Databases
using referrals, Creating Suffix Referrals Using the Console
on update only, Creating Suffix Referrals Using the Console
with multiple databases, Adding Multiple Databases for a Single Suffix
suffix referrals
creating, Creating Suffix Referrals
creating from command line, Creating Suffix Referrals from the Command Line
creating from console, Creating Suffix Referrals Using the Console
supplier bind DN, Replication Identity
supplier server, Suppliers and Consumers
suppliers
purging old entries from the RUV, Resolving Errors for Obsolete or Missing Suppliers
sycnronization
POSIX attributes
configuring sync for, Synchronizing POSIX Attributes for Users and Groups
not syncing object classes, Synchronizing POSIX Attributes for Users and Groups
symbols
'', in ldapsearch, Using Special Characters
::, in LDIF statements, Base-64 Encoding
<, in LDIF statements, Standard LDIF Notation
synchronization
subtree scope and deleting entries, Handling Entries That Move Out of the Synchronized Subtree
synchronization agreement
changing, Modifying the Synchronization Agreement, Adding and Editing the Synchronization Agreement in the Command Line
synchronization options
enabling, Allowing Sync Attributes for Entries
overview, Allowing Sync Attributes for Entries
synchronizing
passwords, Synchronizing Passwords
syntax
LDAP URLs, Components of an LDAP URL
ldapsearch, ldapsearch Command-Line Format
matching rule filter, Using Matching Rules
search filter, LDAP Search Filters
syntax validation, Using Syntax Validation
and error logging, Enabling Syntax Validation Warnings (Logging)
and warnings, Enabling Syntax Validation Warnings (Logging)
command-line perl script, Validating the Syntax of Existing Attribute Values
enabling and disabling, Enabling or Disabling Syntax Validation
enforcing DNs, Enabling Strict Syntax Validation for DNs
related RFCs, About Syntax Validation
syntax-validate.pl, Validating the Syntax of Existing Attribute Values
system connections
monitoring, Monitoring the Server from the Directory Server Console
system resources
monitoring, Monitoring the Server from the Directory Server Console

T

tables
changing column position in, Reordering Table Columns
tabs, in Red Hat Management Console, Red Hat Management Console Tabs
tasks
purging old entries from the RUV, Resolving Errors for Obsolete or Missing Suppliers
template entry. See CoS template entry., About the CoS Template Entry
thread
monitoring, Monitoring the Server from the Directory Server Console
time format, About Locales
timeout period
for replication, Setting Replication Timeout Periods
TLS, Working with TLS
Administration Server password file, Creating a Password File for the Administration Server
and replication, Replication over TLS
CA certificate error messages, Managing Certificates Used by the Directory Server Console
certificate-based authentication, Using Certificate-based Client Authentication
certificates, Managing Certificates for Administration Server
chaining with, Creating a New Database Link Using the Console, Providing an LDAP URL
loading PKCS#11 modules, Using Hardware Security Modules
managing certificates for the Directory Server Console, Managing Certificates Used by the Directory Server Console
port number, Changing the LDAPS Port Numbers
requiring for connections, Requiring Secure Connections
requiring secure binds, Requiring Secure Binds
setting encryption ciphers, Setting Encryption Ciphers
using hardware security modules, Using Hardware Security Modules
using with Administration Server, Enabling TLS
tombstone entries
purging, Managing Deleted Entries with Replication
topology
defined, The Servers and Applications Tab
transaction logs
moving, Changing the Transaction Log Directory

U

unauthenticated binds, Allowing Unauthenticated Binds
uniqueness-top-entry-oc keyword, Configuring Attribute Uniqueness over Object Classes
user and group management
referential integrity, Maintaining Referential Integrity
user directory
settings, Changing the User Directory Host or Port
user entries
changing passwords for, Editing Entries
creating, Directory and Administrative Users
editing, Editing Entries
locating, Searching for Users and Groups
removing, Removing an Entry from the Directory
user passwords, Setting User Passwords
user-defined object classes, Viewing Attributes and Object Classes
user-level password policy, Configuring a Local Password Policy
users
activating, Activating and Inactivating Users and Roles Using the Console
inactivating, Manually Inactivating Users and Roles
Users and Groups tab, changing the search directory for, Searching for Users and Groups
UTF-8, Internationalization

V

viewing
access control
get effective rights, Checking Access Rights on Entries (Get Effective Rights)
attributes, Viewing Attributes and Object Classes
object classes, Viewing Attributes and Object Classes
viewing server information, Viewing Server Information
viewing server logs, Viewing Server Logs
virtual list view index, About Index Types
vlvindex command-line tool, About Index Types

Appendix H. Revision History

Note that revision numbers relate to the edition of this manual, not to version numbers of Red Hat Directory Server.
Revision History
Revision 10.3-1Wed Oct 24 2018Marc Muehlfeld
Red Hat Directory Server 10.3 release of the guide.
Revision 10.2-1Tue Apr 10 2018Marc Muehlfeld
For version 10.2: Added section Comparing Two Directory Server Instances, updated How password policy controls work, Solving Common Replication Conflicts, and Solving Naming Conflicts.
Revision 10.1-17Mon Mar 12 2018Marc Muehlfeld
Rewrote large parts of the Managing Access Control chapter.
Revision 10.1-16Wed Feb 14 2018Marc Muehlfeld
Rewrote Setting up an SNMP Agent for Directory Server. Added Generating and Installing a Self-signed Certificate.
Revision 10.1-15Wed Jan 17 2018Marc Muehlfeld
Rewrote Enabling TLS section. Added Configuring Replication Partners to use Certificate-based Authentication section.
Revision 10.1-14Tue Dec 05 2017Marc Muehlfeld
Enhanced the Managing the NSS Database Used by Directory Server, Using Certificate-based Client Authentication and Setting Encryption Ciphers sections.
Revision 10.1-13Mon Nov 06 2017Marc Muehlfeld
Moved Setting Replication Session Hooks section to the Plug-in Guide. Several minor updates.
Revision 10.1-11Tue Aug 08 2017Marc Muehlfeld
Rewrote the Managing Entries Using the Command Line and Enforcing Attribute Uniqueness sections.
Revision 10.1-10Tue Aug 01 2017Marc Muehlfeld
For version 10.1.1: Added the Managing FIPS Mode Support chapter. Rewrote the Managing the Directory Manager Password and Validating the Syntax of Existing Attribute Values sections. Multiple minor updates.
Revision 10.1-9Mon Jul 31 2017Marc Muehlfeld
Rewrote: Enabling and Disabling Referential Integrity section. Updated replication-related screen captures. Multiple minor updates.
Revision 10.1-8Wed Jul 12 2017Marc Muehlfeld
Added sections: Configuring Plug-ins and Starting the Directory Server Management Console. Multiple minor updates.
Revision 10.1-7Mon Jun 26 2017Marc Muehlfeld
Rewrote sections: Trimming the Replication Changelog and Moving the Replication Changelog Directory.
Revision 10.1-6Mon May 29 2017Marc Muehlfeld
Updated section: Setting Access Control for VLV Information.
Revision 10.1-5Tue Mar 14 2017Marc Muehlfeld
Added section: The Replication Keep-alive Entry.
Revision 10.1-4Fri Feb 24 2017Marc Muehlfeld
Added sections: Fine Grained ID List Size, Trimming the Replication Changelog, and Setting up Content Synchronization with an RFC 4533-aware LDAP Servers. Other minor fixes.
Revision 10.1-3Wed Jan 11 2017Marc Muehlfeld
Rewrote section: Configuring Log Files. Updated replicate_now.sh example.
Revision 10.1-1Fri Nov 11 2016Marc Muehlfeld
Updated supported JRE version. Removed legacy replication support. Other minor fixes.
Revision 10.1-0Mon Oct 31 2016Marc Muehlfeld
Red Hat Directory Server 10.1 release of the guide.
Revision 10.0-3Wed Jun 22 2016Petr Bokoč
Updated section: Enabling TLS/SSL in the Directory Server, Administration Server, and Console. Other minor updates.
Revision 10.0-2Thu Mar 24 2016Petr Bokoč
Updated section: Schema Replication. Added section: High-resolution Time Stamps. Other minor fixes.
Revision 10.0-1Wed Jun 17 2015Tomáš Čapek
Updated section: System Requirements
Revision 10.0-0Tue Jun 09 2015Tomáš Čapek
Red Hat Directory Server 10 release of the guide.

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