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SLAPD.ACCESS(5)                                                                              SLAPD.ACCESS(5)



NAME
       slapd.access - access configuration for slapd, the stand-alone LDAP daemon

SYNOPSIS
       /etc/openldap/slapd.conf

DESCRIPTION
       The slapd.conf(5) file contains configuration information for the slapd(8) daemon. This configuration
       file is also used by the SLAPD tools  slapacl(8),  slapadd(8),  slapauth(8),  slapcat(8),  slapdn(8),
       slapindex(8), and slaptest(8).

       The  slapd.conf  file  consists  of a series of global configuration options that apply to slapd as a
       whole (including all backends), followed by zero or more database backend  definitions  that  contain
       information specific to a backend instance.

       The general format of slapd.conf is as follows:

           # comment - these options apply to every database
           <global configuration options>
           # first database definition & configuration options
           database    <backend 1 type>
           <configuration options specific to backend 1>
           # subsequent database definitions & configuration options
           ...

       Both  the  global  configuration  and  each  backend-specific section can contain access information.
       Backend-specific access control directives are used for those entries that  belong  to  the  backend,
       according to their naming context.  In case no access control directives are defined for a backend or
       those which are defined are not applicable, the directives from the global configuration section  are
       then used.

       If no access controls are present, the default policy allows anyone and everyone to read anything but
       restricts updates to rootdn.  (e.g., "access to * by * read").  The rootdn can always read and  write
       EVERYTHING!

       For  entries  not  held in any backend (such as a root DSE), the directives of the first backend (and
       any global directives) are used.

       Arguments that should be replaced by actual text are shown in brackets <>.

THE ACCESS DIRECTIVE
       The structure of the access control directives is

       access to <what> [ by <who> [ <access> ] [ <control> ] ]+
              Grant access (specified by <access>) to a set  of  entries  and/or  attributes  (specified  by
              <what>) by one or more requestors (specified by <who>).


       Lists  of  access  directives  are  evaluated  in the order they appear in slapd.conf.  When a <what>
       clause matches the datum whose access is being evaluated, its <who> clause list is checked.   When  a
       <who>  clause  matches  the  accessor's properties, its <access> and <control> clauses are evaluated.
       Access control checking stops at the first match of the <what> and  <who>  clause,  unless  otherwise
       dictated by the <control> clause.  Each <who> clause list is implicitly terminated by a

            by * none stop

       clause  that  results  in stopping the access control with no access privileges granted.  Each <what>
       clause list is implicitly terminated by a

            access to *
                 by * none

       clause that results in granting no access privileges to an otherwise unspecified datum.

THE <WHAT> FIELD
       The field <what> specifies the entity the access control directive applies to.  It can have the forms

            dn[.<dnstyle>]=<dnpattern>
            filter=<ldapfilter>
            attrs=<attrlist>[ val[/matchingRule][.<attrstyle>]=<attrval>]

       with

            <dnstyle>={{exact|base(object)}|regex
                 |one(level)|sub(tree)|children}
            <attrlist>={<attr>|[{!|@}]<objectClass>}[,<attrlist>]
            <attrstyle>={{exact|base(object)}|regex
                 |one(level)|sub(tree)|children}

       The statement dn=<dnpattern> selects the entries based on their naming context.  The <dnpattern> is a
       string representation of the entry's DN.  The wildcard * stands  for  all  the  entries,  and  it  is
       implied if no dn form is given.

       The <dnstyle> is optional; however, it is recommended to specify it to avoid ambiguities.  Base (syn-onym (synonym
       onym of baseObject), the default, or exact (an alias of base) indicates the entry whose DN  is  equal
       to the <dnpattern>; one (synonym of onelevel) indicates all the entries immediately below the <dnpat-
       tern>, sub (synonym of subtree) indicates all entries in the subtree  at  the  <dnpattern>,  children
       indicates all the entries below (subordinate to) the <dnpattern>.

       If  the  <dnstyle>  qualifier is regex, then <dnpattern> is a POSIX (''extended'') regular expression
       pattern, as detailed in regex(7) and/or re_format(7), matching a normalized string representation  of
       the entry's DN.  The regex form of the pattern does not (yet) support UTF-8.

       The  statement  filter=<ldapfilter>  selects the entries based on a valid LDAP filter as described in
       RFC 4515.  A filter of (objectClass=*) is implied if no filter form is given.

       The statement attrs=<attrlist> selects the attributes the access control rule applies to.   It  is  a
       comma-separated list of attribute types, plus the special names entry, indicating access to the entry
       itself, and children, indicating access to the entry's children. ObjectClass names may also be speci-fied specified
       fied  in  this  list,  which  will affect all the attributes that are required and/or allowed by that
       objectClass.  Actually, names in <attrlist> that are prefixed by @ are directly  treated  as  object-Class objectClass
       Class  names.   A  name prefixed by !  is also treated as an objectClass, but in this case the access
       rule affects the attributes that are not required nor allowed by that objectClass.  If no attrs  form
       is given, attrs=@extensibleObject is implied, i.e. all attributes are addressed.

       Using the form attrs=<attr> val[/matchingRule][.<attrstyle>]=<attrval> specifies access to a particu-lar particular
       lar value of a single attribute.  In this case, only a  single  attribute  type  may  be  given.  The
       <attrstyle>  exact  (the  default)  uses the attribute's equality matching rule to compare the value,
       unless a different (and compatible) matching rule is specified. If the <attrstyle> is regex, the pro-vided provided
       vided  value  is  used as a POSIX (''extended'') regular expression pattern.  If the attribute has DN
       syntax, the <attrstyle> can be any of  base,  onelevel,  subtree  or  children,  resulting  in  base,
       onelevel, subtree or children match, respectively.

       The  dn,  filter,  and attrs statements are additive; they can be used in sequence to select entities
       the access rule applies to based on naming context, value and attribute type simultaneously.

THE <WHO> FIELD
       The field <who> indicates whom the access rules apply to.  Multiple <who> statements can appear in an
       access  control statement, indicating the different access privileges to the same resource that apply
       to different accessee.  It can have the forms

            *
            anonymous
            users
            self[.<selfstyle>]

            dn[.<dnstyle>[,<modifier>]]=<DN>
            dnattr=<attrname>

            realanonymous
            realusers
            realself[.<selfstyle>]

            realdn[.<dnstyle>[,<modifier>]]=<DN>
            realdnattr=<attrname>

            group[/<objectclass>[/<attrname>]]
                 [.<groupstyle>]=<group>
            peername[.<peernamestyle>]=<peername>
            sockname[.<style>]=<sockname>
            domain[.<domainstyle>[,<modifier>]]=<domain>
            sockurl[.<style>]=<sockurl>
            set[.<setstyle>]=<pattern>

            ssf=<n>
            transport_ssf=<n>
            tls_ssf=<n>
            sasl_ssf=<n>

            dynacl/<name>[/<options>][.<dynstyle>][=<pattern>]

       with

            <style>={exact|regex|expand}
            <selfstyle>={level{<n>}}
            <dnstyle>={{exact|base(object)}|regex
                 |one(level)|sub(tree)|children|level{<n>}}
            <groupstyle>={exact|expand}
            <peernamestyle>={<style>|ip|ipv6|path}
            <domainstyle>={exact|regex|sub(tree)}
            <setstyle>={exact|regex}
            <modifier>={expand}
            <name>=aci          <pattern>=<attrname>]

       They may be specified in combination.


       The wildcard * refers to everybody.

       The keywords prefixed by real act as their counterparts without  prefix;  the  checking  respectively
       occurs with the authentication DN and the authorization DN.

       The  keyword anonymous means access is granted to unauthenticated clients; it is mostly used to limit
       access to authentication resources (e.g. the userPassword attribute) to unauthenticated  clients  for
       authentication purposes.

       The keyword users means access is granted to authenticated clients.

       The  keyword  self  means  access  to  an  entry is allowed to the entry itself (e.g. the entry being
       accessed and the requesting entry must be the same).  It allows the level{<n>} style, where <n> indi-cates indicates
       cates  what  ancestor of the DN is to be used in matches.  A positive value indicates that the <n>-th
       ancestor of the user's DN is to be considered; a negative value indicates that the <n>-th ancestor of
       the  target  is  to be considered.  For example, a "by self.level{1} ..." clause would match when the
       object "dc=example,dc=com" is accessed by "cn=User,dc=example,dc=com".   A  "by  self.level{-1}  ..."
       clause  would  match  when  the  same  user  accesses  the  object  "ou=Address Book,cn=User,dc=exam-ple,dc=com". Book,cn=User,dc=example,dc=com".
       ple,dc=com".

       The statement dn=<DN> means that access is granted to the matching DN.  The optional style  qualifier
       dnstyle allows the same choices of the dn form of the <what> field.  In addition, the regex style can
       exploit substring substitution of submatches  in  the  <what>  dn.regex  clause  by  using  the  form
       $<digit>,  with  digit  ranging  from  0  to  9  (where  0  matches  the  entire string), or the form
       ${<digit>+}, for submatches higher than 9.  Since the dollar character is used  to  indicate  a  sub-string substring
       string  replacement,  the dollar character that is used to indicate match up to the end of the string
       must be escaped by a second dollar character, e.g.

           access to dn.regex="^(.+,)?uid=([^,]+),dc=[^,]+,dc=com$"
               by dn.regex="^uid=$2,dc=[^,]+,dc=com$$" write

       The style qualifier allows an optional modifier.  At present, the only type allowed is expand,  which
       causes  substring  substitution  of submatches to take place even if dnstyle is not regex.  Note that
       the regex dnstyle in the above example may be of use only if the <by> clause needs  to  be  a  regex;
       otherwise,  if  the  value  of the second (from the right) dc= portion of the DN in the above example
       were fixed, the form

           access to dn.regex="^(.+,)?uid=([^,]+),dc=example,dc=com$"
               by dn.exact,expand="uid=$2,dc=example,dc=com" write

       could be used; if it had to match the value in the <what> clause, the form

           access to dn.regex="^(.+,)?uid=([^,]+),dc=([^,]+),dc=com$"
               by dn.exact,expand="uid=$2,dc=$3,dc=com" write

       could be used.

       Forms of the <what> clause other than regex may provide submatches as well.   The  base(object),  the
       sub(tree),  the one(level), and the children forms provide $0 as the match of the entire string.  The
       sub(tree), the one(level), and the children forms also provide $1 as the match of the rightmost  part
       of  the  DN  as defined in the <what> clause.  This may be useful, for instance, to provide access to
       all the ancestors of a user by defining

           access to dn.subtree="dc=com"
               by dn.subtree,expand="$1" read

       which means that only access to entries that appear in the DN of the <by> clause is allowed.

       The level{<n>} form is an extension and a generalization of the onelevel form, which matches all  DNs
       whose <n>-th ancestor is the pattern.  So, level{1} is equivalent to onelevel, and level{_} is equiv-alent equivalent
       alent to base.

       It is perfectly useless to give any access privileges to a DN that exactly matches the rootdn of  the
       database  the  ACLs apply to, because it implicitly possesses write privileges for the entire tree of
       that database.  Actually, access control is bypassed for the rootdn, to solve the intrinsic  chicken-and-egg chickenand-egg
       and-egg problem.

       The  statement  dnattr=<attrname>  means that access is granted to requests whose DN is listed in the
       entry being accessed under the <attrname> attribute.

       The statement group=<group> means that access is granted to requests whose DN is listed in the  group
       entry  whose DN is given by <group>.  The optional parameters <objectclass> and <attrname> define the
       objectClass and the member attributeType of the group entry.  The defaults are groupOfNames and  mem-ber, member,
       ber, respectively.  The optional style qualifier <style> can be expand, which means that <group> will
       be expanded as a replacement string (but not as a regular expression) according  to  regex(7)  and/or
       re_format(7),  and  exact, which means that exact match will be used.  If the style of the DN portion
       of the <what> clause is regex, the submatches are made available according to regex(7) and/or re_for-mat(7); re_format(7);
       mat(7);  other  styles  provide  limited  submatches as discussed above about the DN form of the <by>
       clause.

       For static groups, the specified attributeType must have DistinguishedName or NameAndOptionalUID syn-tax. syntax.
       tax.  For  dynamic  groups  the attributeType must be a subtype of the labeledURI attributeType. Only
       LDAP URIs of the form ldap:///<base>??<scope>?<filter> will be  evaluated  in  a  dynamic  group,  by
       searching the local server only.

       The  statements peername=<peername>, sockname=<sockname>, domain=<domain>, and sockurl=<sockurl> mean
       that the contacting host IP (in the form IP=<ip>:<port> for IPv4, or IP=[<ipv6>]:<port> for IPv6)  or
       the contacting host named pipe file name (in the form PATH=<path> if connecting through a named pipe)
       for peername, the named pipe file name for sockname, the contacting host name  for  domain,  and  the
       contacting  URL  for  sockurl are compared against pattern to determine access.  The same style rules
       for pattern match described for the group case apply, plus the regex style,  which  implies  submatch
       expand and regex match of the corresponding connection parameters.  The exact style of the <peername>
       clause (the default) implies a case-exact match on the client's IP, including the IP= prefix and  the
       trailing  :<port>,  or  the  client's  path, including the PATH= prefix if connecting through a named
       pipe.  The special ip style interprets the pattern as <peername>=<ip>[%<mask>][{<n>}], where <ip> and
       <mask>  are dotted digit representations of the IP and the mask, while <n>, delimited by curly brack-ets, brackets,
       ets, is an optional port.  The same applies to IPv6 addresses when the special ipv6  style  is  used.
       When  checking  access  privileges,  the IP portion of the peername is extracted, eliminating the IP=
       prefix and the :<port> part, and it is compared against the <ip> portion of the pattern after masking
       with  <mask>:  ((peername  &  <mask>)  ==  <ip>).   As  an  example,  peername.ip=127.0.0.1 and peer-name.ipv6=::1 peername.ipv6=::1
       name.ipv6=::1 allow connections only  from  localhost,  peername.ip=192.168.1.0%255.255.255.0  allows
       connections     from     any    IP    in    the    192.168.1    class    C    domain,    and    peer-name.ip=192.168.1.16%255.255.255.240{9009} peername.ip=192.168.1.16%255.255.255.240{9009}
       name.ip=192.168.1.16%255.255.255.240{9009} allows connections from any IP  in  the  192.168.1.[16-31]
       range  of  the  same  domain, only if port 9009 is used.  The special path style eliminates the PATH=
       prefix from the peername when connecting through a named pipe, and performs an  exact  match  on  the
       given pattern.  The <domain> clause also allows the subtree style, which succeeds when a fully quali-fied qualified
       fied name exactly matches the domain pattern, or its trailing part, after a dot, exactly matches  the
       domain  pattern.   The  expand style is allowed, implying an exact match with submatch expansion; the
       use of expand as a style modifier  is  considered  more  appropriate.   As  an  example,  domain.sub-tree=example.com domain.subtree=example.com
       tree=example.com  will  match www.example.com, but will not match www.anotherexample.com.  The domain
       of the contacting host is determined by performing a DNS reverse lookup.  As this lookup  can  easily
       be  spoofed,  use  of  the domain statement is strongly discouraged.  By default, reverse lookups are
       disabled.  The optional domainstyle qualifier of the <domain> clause allows a  modifier  option;  the
       only  value  currently supported is expand, which causes substring substitution of submatches to take
       place even if the domainstyle is not regex, much like the analogous usage in <dn> clause.

       The statement set=<pattern> is undocumented yet.

       The statement dynacl/<name>[/<options>][.<dynstyle>][=<pattern>] means that access checking is  dele-gated delegated
       gated  to  the admin-defined method indicated by <name>, which can be registered at run-time by means
       of the moduleload statement.  The fields <options>, <dynstyle> and <pattern> are  optional,  and  are
       directly  passed  to  the  registered parsing routine.  Dynacl is experimental; it must be enabled at
       compile time.

       The statement dynacl/aci[=<attrname>] means that the access control is determined by  the  values  in
       the attrname of the entry itself.  The optional <attrname> indicates what attributeType holds the ACI
       information in the entry.  By default, the OpenLDAPaci  operational  attribute  is  used.   ACIs  are
       experimental; they must be enabled at compile time.

       The  statements  ssf=<n>,  transport_ssf=<n>,  tls_ssf=<n>, and sasl_ssf=<n> set the minimum required
       Security Strength Factor (ssf) needed to grant access.  The value should be positive integer.

THE <ACCESS> FIELD
       The optional field <access> ::= [[real]self]{<level>|<priv>} determines the access level or the  spe-cific specific
       cific access privileges the who field will have.  Its component are defined as

            <level> ::= none|disclose|auth|compare|search|read|{write|add|delete}|manage
            <priv> ::= {=|+|-}{0|d|x|c|s|r|{w|a|z}|m}+

       The  modifier  self allows special operations like having a certain access level or privilege only in
       case the operation involves the name of the user that's requesting the access.  It implies  the  user
       that  requests access is authorized.  The modifier realself refers to the authenticated DN as opposed
       to the authorized DN of the self modifier.   An  example  is  the  selfwrite  access  to  the  member
       attribute  of  a  group,  which  allows one to add/delete its own DN from the member list of a group,
       without affecting other members.

       The level access model relies on an incremental interpretation of the access privileges.  The  possi-ble possible
       ble  levels  are  none,  disclose, auth, compare, search, read, write, and manage.  Each access level
       implies all the preceding ones, thus manage grants all access including administrative  access.   The
       write  access  is  actually  the combination of add and delete, which respectively restrict the write
       privilege to add or delete the specified <what>.


       The none access level disallows all access including disclosure on error.

       The disclose access level allows disclosure of information on error.

       The auth access level means that one is  allowed  access  to  an  attribute  to  perform  authentica-tion/authorization authentication/authorization
       tion/authorization operations (e.g.  bind) with no other access.  This is useful to grant unauthenti-cated unauthenticated
       cated clients the least possible access level to critical resources, like passwords.

       The priv access model relies on the explicit setting of access privileges for  each  clause.   The  =
       sign  resets  previously defined accesses; as a consequence, the final access privileges will be only
       those defined by the clause.  The + and - signs add/remove access privileges to  the  existing  ones.
       The  privileges  are  m for manage, w for write, a for add, z for delete, r for read, s for search, c
       for compare, x for authentication, and d for disclose.  More than one of the above privileges can  be
       added  in one statement.  0 indicates no privileges and is used only by itself (e.g., +0).  Note that
       +az is equivalent to +w.

       If no access is given, it defaults to +0.

THE <CONTROL> FIELD
       The optional field <control> controls the flow of access rule application.  It can have the forms

            stop
            continue
            break

       where stop, the default, means access checking stops in case of match.  The other two forms are  used
       to keep on processing access clauses.  In detail, the continue form allows for other <who> clauses in
       the same <access> clause to be considered, so that they may  result  in  incrementally  altering  the
       privileges,  while  the break form allows for other <access> clauses that match the same target to be
       processed.  Consider the (silly) example

            access to dn.subtree="dc=example,dc=com" attrs=cn
                 by * =cs break

            access to dn.subtree="ou=People,dc=example,dc=com"
                 by * +r

       which allows search and compare privileges to everybody under the "dc=example,dc=com" tree, with  the
       second rule allowing also read in the "ou=People" subtree, or the (even more silly) example

            access to dn.subtree="dc=example,dc=com" attrs=cn
                 by * =cs continue
                 by users +r

       which  grants  everybody  search  and  compare  privileges, and adds read privileges to authenticated
       clients.

       One useful application is to easily grant write privileges to an updatedn that is different from  the
       rootdn.  In this case, since the updatedn needs write access to (almost) all data, one can use

            access to *
                 by dn.exact="cn=The Update DN,dc=example,dc=com" write
                 by * break

       as  the  first  access  rule.   As a consequence, unless the operation is performed with the updatedn
       identity, control is passed straight to the subsequent rules.


OPERATION REQUIREMENTS
       Operations require different privileges on different portions  of  entries.   The  following  summary
       applies to primary database backends such as the BDB and HDB backends.   Requirements for other back-ends backends
       ends may (and often do) differ.


       The add operation requires add (=a) privileges on the  pseudo-attribute  entry  of  the  entry  being
       added,  and  add (=a) privileges on the pseudo-attribute children of the entry's parent.  When adding
       the suffix entry of a database, add access to children of the empty DN ("") is required.


       The bind operation, when credentials are stored in the directory, requires auth  (=x)  privileges  on
       the attribute the credentials are stored in (usually userPassword).


       The compare operation requires compare (=c) privileges on the attribute that is being compared.


       The delete operation requires delete (=z) privileges on the pseudo-attribute entry of the entry being
       deleted, and delete (=d) privileges on the children pseudo-attribute of the entry's parent.


       The modify operation requires write (=w) privileges on the attributes being modified.  In detail, add
       (=a)  is  required  to  add  new  values, delete (=z) is required to delete existing values, and both
       delete and add (=az), or write (=w), are required to replace existing values.


       The modrdn operation requires write (=w) privileges on the pseudo-attribute entry of the entry  whose
       relative  DN  is  being  modified, delete (=z) privileges on the pseudo-attribute children of the old
       entry's parents, add (=a) privileges on the pseudo-attribute children of the new entry's parents, and
       add  (=a)  privileges  on the attributes that are present in the new relative DN.  Delete (=z) privi-leges privileges
       leges are also required on the attributes that are present in the old relative DN if deleteoldrdn  is
       set to 1.


       The search operation, requires search (=s) privileges on the entry pseudo-attribute of the searchBase
       (NOTE: this was introduced with OpenLDAP 2.4).  Then, for each entry, it requires search (=s)  privi-leges privileges
       leges on the attributes that are defined in the filter.  The resulting entries are finally tested for
       read (=r) privileges on the pseudo-attribute entry (for read access to the entry itself) and for read
       (=r)  access  on each value of each attribute that is requested.  Also, for each referral object used
       in generating continuation references, the  operation  requires  read  (=r)  access  on  the  pseudo-attribute pseudoattribute
       attribute  entry  (for read access to the referral object itself), as well as read (=r) access to the
       attribute holding the referral information (generally the ref attribute).


       Some internal operations and some controls require specific access privileges.  The  authzID  mapping
       and the proxyAuthz control require auth (=x) privileges on all the attributes that are present in the
       search filter of the URI regexp maps (the right-hand side of the authz-regexp directives).  Auth (=x)
       privileges  are  also  required  on  the  authzTo attribute of the authorizing identity and/or on the
       authzFrom attribute of the authorized identity.  In general, when an internal lookup is performed for
       authentication or authorization purposes, search-specific privileges (see the access requirements for
       the search operation illustrated above) are relaxed to auth.


       Access control to search entries is checked by the frontend, so it is fully honored by all  backends;
       for  all  other operations and for the discovery phase of the search operation, full ACL semantics is
       only supported by the primary backends, i.e.  back-bdb(5), and back-hdb(5).

       Some other backend, like back-sql(5), may fully support them; others may only support  a  portion  of
       the  described  semantics, or even differ in some aspects.  The relevant details are described in the
       backend-specific man pages.


CAVEATS
       It is strongly recommended to explicitly use the most  appropriate  <dnstyle>  in  <what>  and  <who>
       clauses,  to  avoid  possible incorrect specifications of the access rules as well as for performance
       (avoid unnecessary regex matching when an exact match suffices) reasons.

       An administrator might create a rule of the form:

            access to dn.regex="dc=example,dc=com"
                 by ...

       expecting it to match all entries in the subtree "dc=example,dc=com".  However,  this  rule  actually
       matches  any DN which contains anywhere the substring "dc=example,dc=com".  That is, the rule matches
       both "uid=joe,dc=example,dc=com" and "dc=example,dc=com,uid=joe".

       To match the desired subtree, the rule would be more precisely written:

            access to dn.regex="^(.+,)?dc=example,dc=com$"
                 by ...

       For performance reasons, it would be better to use the subtree style.

            access to dn.subtree="dc=example,dc=com"
                 by ...

       When writing submatch rules, it may be convenient to  avoid  unnecessary  regex  <dnstyle>  use;  for
       instance, to allow access to the subtree of the user that matches the <what> clause, one could use

            access to dn.regex="^(.+,)?uid=([^,]+),dc=example,dc=com$"
                 by dn.regex="^uid=$2,dc=example,dc=com$$" write
                 by ...

       However, since all that is required in the <by> clause is substring expansion, a more efficient solu-tion solution
       tion is

            access to dn.regex="^(.+,)?uid=([^,]+),dc=example,dc=com$"
                 by dn.exact,expand="uid=$2,dc=example,dc=com" write
                 by ...

       In fact, while a <dnstyle> of regex implies substring expansion, exact, as well as all the  other  DN
       specific <dnstyle> values, does not, so it must be explicitly requested.


FILES
       /etc/openldap/slapd.conf
              default slapd configuration file

SEE ALSO
       slapd(8), slapd-*(5), slapacl(8), regex(7), re_format(7)

       "OpenLDAP Administrator's Guide" (http://www.OpenLDAP.org/doc/admin/)

ACKNOWLEDGEMENTS
       OpenLDAP  Software  is  developed  and maintained by The OpenLDAP Project <http://www.openldap.org/>.
       OpenLDAP Software is derived from University of Michigan LDAP 3.3 Release.



OpenLDAP 2.4.11                                  2008/07/16                                  SLAPD.ACCESS(5)

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