LDAP is often used by organizations as a central repository for user information and as an authentication service. It can also be used to store the role information for application users.
There are many different scenarios for how an LDAP server may be configured so Spring Security’s LDAP provider is fully configurable. It uses separate strategy interfaces for authentication and role retrieval and provides default implementations which can be configured to handle a wide range of situations.
You should be familiar with LDAP before trying to use it with Spring Security. The following link provides a good introduction to the concepts involved and a guide to setting up a directory using the free LDAP server OpenLDAP: http://www.zytrax.com/books/ldap/. Some familiarity with the JNDI APIs used to access LDAP from Java may also be useful. We don’t use any third-party LDAP libraries (Mozilla, JLDAP etc.) in the LDAP provider, but extensive use is made of Spring LDAP, so some familiarity with that project may be useful if you plan on adding your own customizations.
When using LDAP authentication, it is important to ensure that you configure LDAP connection pooling properly. If you are unfamiliar with how to do this, you can refer to the Java LDAP documentation.
LDAP authentication in Spring Security can be roughly divided into the following stages.
The exception is when the LDAP directory is just being used to retrieve user information and authenticate against it locally. This may not be possible as directories are often set up with limited read access for attributes such as user passwords.
We will look at some configuration scenarios below. For full information on available configuration options, please consult the security namespace schema (information from which should be available in your XML editor).
The first thing you need to do is configure the server against which authentication should take place. This is done using the <ldap-server>
element from the security namespace. This can be configured to point at an external LDAP server, using the url
attribute:
<ldap-server url="ldap://springframework.org:389/dc=springframework,dc=org" />
The <ldap-server>
element can also be used to create an embedded server, which can be very useful for testing and demonstrations. In this case you use it without the url
attribute:
<ldap-server root="dc=springframework,dc=org"/>
Here we’ve specified that the root DIT of the directory should be "dc=springframework,dc=org", which is the default. Used this way, the namespace parser will create an embedded Apache Directory server and scan the classpath for any LDIF files, which it will attempt to load into the server. You can customize this behaviour using the ldif
attribute, which defines an LDIF resource to be loaded:
<ldap-server ldif="classpath:users.ldif" />
This makes it a lot easier to get up and running with LDAP, since it can be inconvenient to work all the time with an external server. It also insulates the user from the complex bean configuration needed to wire up an Apache Directory server. Using plain Spring Beans the configuration would be much more cluttered. You must have the necessary Apache Directory dependency jars available for your application to use. These can be obtained from the LDAP sample application.
This is the most common LDAP authentication scenario.
<ldap-authentication-provider user-dn-pattern="uid={0},ou=people"/>
This simple example would obtain the DN for the user by substituting the user login name in the supplied pattern and attempting to bind as that user with the login password. This is OK if all your users are stored under a single node in the directory. If instead you wished to configure an LDAP search filter to locate the user, you could use the following:
<ldap-authentication-provider user-search-filter="(uid={0})" user-search-base="ou=people"/>
If used with the server definition above, this would perform a search under the DN ou=people,dc=springframework,dc=org
using the value of the user-search-filter
attribute as a filter. Again the user login name is substituted for the parameter in the filter name, so it will search for an entry with the uid
attribute equal to the user name. If user-search-base
isn’t supplied, the search will be performed from the root.
How authorities are loaded from groups in the LDAP directory is controlled by the following attributes.
group-search-base
. Defines the part of the directory tree under which group searches should be performed.
group-role-attribute
. The attribute which contains the name of the authority defined by the group entry. Defaults to`cn`
group-search-filter
. The filter which is used to search for group membership. The default is`uniqueMember={0}`, corresponding to the groupOfUniqueNames
LDAP class [19]. In this case, the substituted parameter is the full distinguished name of the user. The parameter {1}
can be used if you want to filter on the login name.
So if we used the following configuration
<ldap-authentication-provider user-dn-pattern="uid={0},ou=people" group-search-base="ou=groups" />
and authenticated successfully as user "ben", the subsequent loading of authorities would perform a search under the directory entry`ou=groups,dc=springframework,dc=org`, looking for entries which contain the attribute uniqueMember
with value uid=ben,ou=people,dc=springframework,dc=org
. By default the authority names will have the prefix ROLE_
prepended. You can change this using the role-prefix
attribute. If you don’t want any prefix, use role-prefix="none"
. For more information on loading authorities, see the Javadoc for the DefaultLdapAuthoritiesPopulator
class.
The namespace configuration options we’ve used above are simple to use and much more concise than using Spring beans explicitly. There are situations when you may need to know how to configure Spring Security LDAP directly in your application context. You may wish to customize the behaviour of some of the classes, for example. If you’re happy using namespace configuration then you can skip this section and the next one.
The main LDAP provider class, LdapAuthenticationProvider
, doesn’t actually do much itself but delegates the work to two other beans, an LdapAuthenticator
and an LdapAuthoritiesPopulator
which are responsible for authenticating the user and retrieving the user’s set of GrantedAuthority
s respectively.
The authenticator is also responsible for retrieving any required user attributes. This is because the permissions on the attributes may depend on the type of authentication being used. For example, if binding as the user, it may be necessary to read them with the user’s own permissions.
There are currently two authentication strategies supplied with Spring Security:
Before it is possible to authenticate a user (by either strategy), the distinguished name (DN) has to be obtained from the login name supplied to the application. This can be done either by simple pattern-matching (by setting the setUserDnPatterns
array property) or by setting the userSearch
property. For the DN pattern-matching approach, a standard Java pattern format is used, and the login name will be substituted for the parameter {0}
. The pattern should be relative to the DN that the configured SpringSecurityContextSource
will bind to (see the section on connecting to the LDAP server for more information on this). For example, if you are using an LDAP server with the URL`ldap://monkeymachine.co.uk/dc=springframework,dc=org`, and have a pattern uid={0},ou=greatapes
, then a login name of "gorilla" will map to a DN`uid=gorilla,ou=greatapes,dc=springframework,dc=org`. Each configured DN pattern will be tried in turn until a match is found. For information on using a search, see the section on search objects below. A combination of the two approaches can also be used - the patterns will be checked first and if no matching DN is found, the search will be used.
The class BindAuthenticator
in the package org.springframework.security.ldap.authentication
implements the bind authentication strategy. It simply attempts to bind as the user.
The beans discussed above have to be able to connect to the server. They both have to be supplied with a SpringSecurityContextSource
which is an extension of Spring LDAP’s ContextSource
. Unless you have special requirements, you will usually configure a DefaultSpringSecurityContextSource
bean, which can be configured with the URL of your LDAP server and optionally with the username and password of a "manager" user which will be used by default when binding to the server (instead of binding anonymously). For more information read the Javadoc for this class and for Spring LDAP’s AbstractContextSource
.
Often a more complicated strategy than simple DN-matching is required to locate a user entry in the directory. This can be encapsulated in an LdapUserSearch
instance which can be supplied to the authenticator implementations, for example, to allow them to locate a user. The supplied implementation is FilterBasedLdapUserSearch
.
This bean uses an LDAP filter to match the user object in the directory. The process is explained in the Javadoc for the corresponding search method on the JDK DirContext class. As explained there, the search filter can be supplied with parameters. For this class, the only valid parameter is {0}
which will be replaced with the user’s login name.
After authenticating the user successfully, the LdapAuthenticationProvider
will attempt to load a set of authorities for the user by calling the configured LdapAuthoritiesPopulator
bean. The DefaultLdapAuthoritiesPopulator
is an implementation which will load the authorities by searching the directory for groups of which the user is a member (typically these will be groupOfNames
or groupOfUniqueNames
entries in the directory). Consult the Javadoc for this class for more details on how it works.
If you want to use LDAP only for authentication, but load the authorities from a difference source (such as a database) then you can provide your own implementation of this interface and inject that instead.
A typical configuration, using some of the beans we’ve discussed here, might look like this:
<bean id="contextSource" class="org.springframework.security.ldap.DefaultSpringSecurityContextSource"> <constructor-arg value="ldap://monkeymachine:389/dc=springframework,dc=org"/> <property name="userDn" value="cn=manager,dc=springframework,dc=org"/> <property name="password" value="password"/> </bean> <bean id="ldapAuthProvider" class="org.springframework.security.ldap.authentication.LdapAuthenticationProvider"> <constructor-arg> <bean class="org.springframework.security.ldap.authentication.BindAuthenticator"> <constructor-arg ref="contextSource"/> <property name="userDnPatterns"> <list><value>uid={0},ou=people</value></list> </property> </bean> </constructor-arg> <constructor-arg> <bean class="org.springframework.security.ldap.userdetails.DefaultLdapAuthoritiesPopulator"> <constructor-arg ref="contextSource"/> <constructor-arg value="ou=groups"/> <property name="groupRoleAttribute" value="ou"/> </bean> </constructor-arg> </bean>
This would set up the provider to access an LDAP server with URL ldap://monkeymachine:389/dc=springframework,dc=org
. Authentication will be performed by attempting to bind with the DN`uid=<user-login-name>,ou=people,dc=springframework,dc=org`. After successful authentication, roles will be assigned to the user by searching under the DN ou=groups,dc=springframework,dc=org
with the default filter (member=<user’s-DN>)
. The role name will be taken from the "ou" attribute of each match.
To configure a user search object, which uses the filter (uid=<user-login-name>)
for use instead of the DN-pattern (or in addition to it), you would configure the following bean
<bean id="userSearch" class="org.springframework.security.ldap.search.FilterBasedLdapUserSearch"> <constructor-arg index="0" value=""/> <constructor-arg index="1" value="(uid={0})"/> <constructor-arg index="2" ref="contextSource" /> </bean>
and use it by setting the BindAuthenticator
bean’s userSearch
property. The authenticator would then call the search object to obtain the correct user’s DN before attempting to bind as this user.
The net result of an authentication using LdapAuthenticationProvider
is the same as a normal Spring Security authentication using the standard UserDetailsService
interface. A UserDetails
object is created and stored in the returned Authentication
object. As with using a UserDetailsService
, a common requirement is to be able to customize this implementation and add extra properties. When using LDAP, these will normally be attributes from the user entry. The creation of the UserDetails
object is controlled by the provider’s UserDetailsContextMapper
strategy, which is responsible for mapping user objects to and from LDAP context data:
public interface UserDetailsContextMapper { UserDetails mapUserFromContext(DirContextOperations ctx, String username, Collection<GrantedAuthority> authorities); void mapUserToContext(UserDetails user, DirContextAdapter ctx); }
Only the first method is relevant for authentication. If you provide an implementation of this interface and inject it into the LdapAuthenticationProvider
, you have control over exactly how the UserDetails object is created. The first parameter is an instance of Spring LDAP’s DirContextOperations
which gives you access to the LDAP attributes which were loaded during authentication. the username
parameter is the name used to authenticate and the final parameter is the collection of authorities loaded for the user by the configured`LdapAuthoritiesPopulator`.
The way the context data is loaded varies slightly depending on the type of authentication you are using. With the BindAuthenticator
, the context returned from the bind operation will be used to read the attributes, otherwise the data will be read using the standard context obtained from the configured ContextSource
(when a search is configured to locate the user, this will be the data returned by the search object).
Active Directory supports its own non-standard authentication options, and the normal usage pattern doesn’t fit too cleanly with the standard LdapAuthenticationProvider
. Typically authentication is performed using the domain username (in the form user@domain
), rather than using an LDAP distinguished name. To make this easier, Spring Security 3.1 has an authentication provider which is customized for a typical Active Directory setup.
Configuring ActiveDirectoryLdapAuthenticationProvider
is quite straightforward. You just need to supply the domain name and an LDAP URL supplying the address of the server [20]. An example configuration would then look like this:
<bean id="adAuthenticationProvider" class="org.springframework.security.ldap.authentication.ad.ActiveDirectoryLdapAuthenticationProvider"> <constructor-arg value="mydomain.com" /> <constructor-arg value="ldap://adserver.mydomain.com/" /> </bean> }
Note that there is no need to specify a separate ContextSource
in order to define the server location - the bean is completely self-contained. A user named "Sharon", for example, would then be able to authenticate by entering either the username sharon
or the full Active Directory userPrincipalName
, namely [email protected]
. The user’s directory entry will then be located, and the attributes returned for possible use in customizing the created UserDetails
object (a UserDetailsContextMapper
can be injected for this purpose, as described above). All interaction with the directory takes place with the identity of the user themselves. There is no concept of a "manager" user.
By default, the user authorities are obtained from the memberOf
attribute values of the user entry. The authorities allocated to the user can again be customized using a UserDetailsContextMapper
. You can also inject a GrantedAuthoritiesMapper
into the provider instance to control the authorities which end up in the Authentication
object.
By default, a failed result will cause a standard Spring Security BadCredentialsException
. If you set the property convertSubErrorCodesToExceptions
to true
, the exception messages will be parsed to attempt to extract the Active Directory-specific error code and raise a more specific exception. Check the class Javadoc for more information.