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Groff
833 lines
29 KiB
Groff
.TH SLAPD-META 5 "RELEASEDATE" "OpenLDAP LDVERSION"
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.\" Copyright 1998-2005 The OpenLDAP Foundation, All Rights Reserved.
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.\" Copying restrictions apply. See the COPYRIGHT file.
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.\" Copyright 2001, Pierangelo Masarati, All rights reserved. <ando@sys-net.it>
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.\" $OpenLDAP$
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.\"
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.\" Portions of this document should probably be moved to slapd-ldap(5)
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.\" and maybe manual pages for librewrite.
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.\"
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.SH NAME
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slapd-meta \- metadirectory backend
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.SH SYNOPSIS
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ETCDIR/slapd.conf
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.SH DESCRIPTION
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The
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.B meta
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backend to
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.BR slapd (8)
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performs basic LDAP proxying with respect to a set of remote LDAP
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servers, called "targets".
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The information contained in these servers can be presented as
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belonging to a single Directory Information Tree (DIT).
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.LP
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A basic knowledge of the functionality of the
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.BR slapd\-ldap (5)
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backend is recommended.
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This backend has been designed as an enhancement of the ldap backend.
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The two backends share many features (actually they also share
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portions of code).
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While the
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.B ldap
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backend is intended to proxy operations directed to a single server, the
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.B meta
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backend is mainly intended for proxying of multiple servers and possibly
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naming context masquerading.
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These features, although useful in many scenarios, may result in
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excessive overhead for some applications, so its use should be
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carefully considered.
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In the examples section, some typical scenarios will be discussed.
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.SH EXAMPLES
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There are examples in various places in this document, as well as in the
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slapd/back-meta/data/ directory in the OpenLDAP source tree.
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.SH CONFIGURATION
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These
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.B slapd.conf
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options apply to the META backend database.
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That is, they must follow a "database meta" line and come before any
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subsequent "backend" or "database" lines.
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Other database options are described in the
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.BR slapd.conf (5)
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manual page.
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.LP
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Note: In early versions of back-ldap and back-meta it was recommended to always set
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.LP
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.RS
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.nf
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lastmod off
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.fi
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.RE
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.LP
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for every
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.B ldap
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and
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.B meta
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database.
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This is because operational attributes related to entry creation and
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modification should not be proxied, as they could be mistakenly written
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to the target server(s), generating an error.
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The current implementation automatically sets lastmod to off, so its use
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is redundant and should be omitted, because the lastmod directive will
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be deprecated in the future.
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.SH SPECIAL CONFIGURATION DIRECTIVES
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Target configuration starts with the "uri" directive.
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All the configuration directives that are not specific to targets
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should be defined first for clarity, including those that are common
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to all backends.
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They are:
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.TP
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.B default-target none
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This directive forces the backend to reject all those operations
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that must resolve to a single target in case none or multiple
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targets are selected.
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They include: add, delete, modify, modrdn; compare is not included, as
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well as bind since, as they don't alter entries, in case of multiple
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matches an attempt is made to perform the operation on any candidate
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target, with the constraint that at most one must succeed.
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This directive can also be used when processing targets to mark a
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specific target as default.
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.TP
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.B dncache-ttl {forever|disabled|<ttl>}
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This directive sets the time-to-live of the DN cache.
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This caches the target that holds a given DN to speed up target
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selection in case multiple targets would result from an uncached
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search; forever means cache never expires; disabled means no DN
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caching; otherwise a valid ( > 0 ) ttl in seconds is required.
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.TP
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.B nretries {forever|never|<nretries>}
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This directive defines how many times a bind should be retried
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in case of temporary failure in contacting a target. If defined
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before any target specification, it applies to all targets (by default,
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.BR never );
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the global value can be overridden by redefinitions inside each target
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specification.
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.SH TARGET SPECIFICATION
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Target specification starts with a "uri" directive:
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.TP
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.B uri <protocol>://[<host>[:<port>]]/<naming context>
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The "server" directive that was allowed in the LDAP backend (although
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deprecated) has been completely discarded in the Meta backend.
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The <protocol> part can be anything
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.BR ldap_initialize (3)
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accepts ({ldap|ldaps|ldapi} and variants); <host> and <port> may be
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omitted, defaulting to whatever is set in
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.BR ldap.conf (5).
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The <naming context> part is mandatory.
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It must end with one of the naming contexts defined for the backend,
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e.g.:
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.LP
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.RS
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.nf
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suffix "\fBdc=foo,dc=com\fP"
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uri "ldap://x.foo.com/dc=x,\fBdc=foo,dc=com\fP"
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.fi
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.RE
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.RS
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The <naming context> part doesn't need to be unique across the targets;
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it may also match one of the values of the "suffix" directive.
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Multiple URIs may be defined in a single argument. The URIs must
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be separated by TABs (e.g. '\\t'; commas or spaces, unlike back-ldap,
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will not work,
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because they are legal in the <naming context>, and we don't want to use
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URL-encoded <naming context>s), and the additional URIs must have
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no <naming context> part. This causes the underlying library
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to contact the first server of the list that responds.
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.RE
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.TP
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.B default-target [<target>]
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The "default-target" directive can also be used during target specification.
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With no arguments it marks the current target as the default.
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The optional number marks target <target> as the default one, starting
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from 1.
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Target <target> must be defined.
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.TP
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.B acl-authcDN "<administrative DN for access control purposes>"
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DN which is used to query the target server for acl checking,
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as in the LDAP backend; it is supposed to have read access
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on the target server to attributes used on the proxy for acl checking.
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There is no risk of giving away such values; they are only used to
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check permissions.
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.B The acl-authcDN identity is by no means implicitly used by the proxy
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.B when the client connects anonymously.
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.TP
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.B acl-passwd <password>
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Password used with the
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.B
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acl-authcDN
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above.
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.TP
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.B rebind-as-user {NO|yes}
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If this option is given, the client's bind credentials are remembered
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for rebinds when chasing referrals.
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.TP
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.B chase-referrals {YES|no}
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enable/disable automatic referral chasing, which is delegated to the
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underlying libldap, with rebinding eventually performed if the
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\fBrebind-as-user\fP directive is used. The default is to chase referrals.
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.TP
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.B tls {[try-]start|[try-]propagate}
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execute the start TLS extended operation when the connection is initialized;
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only works if the URI directive protocol scheme is not \fBldaps://\fP.
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\fBpropagate\fP issues the Start TLS exop only if the original
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connection did.
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The \fBtry-\fP prefix instructs the proxy to continue operations
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if start TLS failed; its use is highly deprecated.
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.TP
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.B t-f-support {NO|yes|discover}
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enable if the remote server supports absolute filters
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(see \fIdraft-zeilenga-ldap-t-f\fP for details).
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If set to
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.BR discover ,
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support is detected by reading the remote server's root DSE.
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.TP
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.B onerr {CONTINUE|stop}
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This directive allows to select the behavior in case an error is returned
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by one target during a search.
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The default, \fBcontinue\fP, consists in continuing the operation,
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trying to return as much data as possible.
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If this statement is set to \fBstop\fP, the search is terminated as soon
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as an error is returned by one target, and the error is immediately
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propagated to the client.
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.TP
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.B pseudorootdn "<substitute DN in case of rootdn bind>"
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This directive, if present, sets the DN that will be substituted to
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the bind DN if a bind with the backend's "rootdn" succeeds.
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The true "rootdn" of the target server ought not be used; an arbitrary
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administrative DN should used instead.
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.TP
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.B pseudorootpw "<substitute password in case of rootdn bind>"
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This directive sets the credential that will be used in case a bind
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with the backend's "rootdn" succeeds, and the bind is propagated to
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the target using the "pseudorootdn" DN.
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Note: cleartext credentials must be supplied here; as a consequence,
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using the pseudorootdn/pseudorootpw directives is inherently unsafe.
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.TP
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.B rewrite* ...
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The rewrite options are described in the "REWRITING" section.
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.TP
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.B suffixmassage "<virtual naming context>" "<real naming context>"
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All the directives starting with "rewrite" refer to the rewrite engine
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that has been added to slapd.
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The "suffixmassage" directive was introduced in the LDAP backend to
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allow suffix massaging while proxying.
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It has been obsoleted by the rewriting tools.
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However, both for backward compatibility and for ease of configuration
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when simple suffix massage is required, it has been preserved.
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It wraps the basic rewriting instructions that perform suffix
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massaging. See the "REWRITING" section for a detailed list
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of the rewrite rules it implies.
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.LP
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Note: this also fixes a flaw in suffix massaging, which operated
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on (case insensitive) DNs instead of normalized DNs,
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so "dc=foo, dc=com" would not match "dc=foo,dc=com".
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.LP
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See the "REWRITING" section.
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.TP
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.B map "{attribute|objectclass} [<local name>|*] {<foreign name>|*}"
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This maps object classes and attributes as in the LDAP backend.
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See
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.BR slapd-ldap (5).
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.SH SCENARIOS
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A powerful (and in some sense dangerous) rewrite engine has been added
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to both the LDAP and Meta backends.
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While the former can gain limited beneficial effects from rewriting
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stuff, the latter can become an amazingly powerful tool.
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.LP
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Consider a couple of scenarios first.
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.LP
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1) Two directory servers share two levels of naming context;
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say "dc=a,dc=foo,dc=com" and "dc=b,dc=foo,dc=com".
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Then, an unambiguous Meta database can be configured as:
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.LP
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.RS
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.nf
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database meta
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suffix "\fBdc=foo,dc=com\fP"
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uri "ldap://a.foo.com/dc=a,\fBdc=foo,dc=com\fP"
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uri "ldap://b.foo.com/dc=b,\fBdc=foo,dc=com\fP"
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.fi
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.RE
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.LP
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Operations directed to a specific target can be easily resolved
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because there are no ambiguities.
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The only operation that may resolve to multiple targets is a search
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with base "dc=foo,dc=com" and scope at least "one", which results in
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spawning two searches to the targets.
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.LP
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2a) Two directory servers don't share any portion of naming context,
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but they'd present as a single DIT
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[Caveat: uniqueness of (massaged) entries among the two servers is
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assumed; integrity checks risk to incur in excessive overhead and have
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not been implemented].
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Say we have "dc=bar,dc=org" and "o=Foo,c=US",
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and we'd like them to appear as branches of "dc=foo,dc=com", say
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"dc=a,dc=foo,dc=com" and "dc=b,dc=foo,dc=com".
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Then we need to configure our Meta backend as:
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.LP
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.RS
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.nf
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database meta
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suffix "dc=foo,dc=com"
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uri "ldap://a.bar.com/\fBdc=a,dc=foo,dc=com\fP"
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suffixmassage "\fBdc=a,dc=foo,dc=com\fP" "dc=bar,dc=org"
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uri "ldap://b.foo.com/\fBdc=b,dc=foo,dc=com\fP"
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suffixmassage "\fBdc=b,dc=foo,dc=com\fP" "o=Foo,c=US"
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.fi
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.RE
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.LP
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Again, operations can be resolved without ambiguity, although
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some rewriting is required.
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Notice that the virtual naming context of each target is a branch of
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the database's naming context; it is rewritten back and forth when
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operations are performed towards the target servers.
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What "back and forth" means will be clarified later.
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.LP
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When a search with base "dc=foo,dc=com" is attempted, if the
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scope is "base" it fails with "no such object"; in fact, the
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common root of the two targets (prior to massaging) does not
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exist.
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If the scope is "one", both targets are contacted with the base
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replaced by each target's base; the scope is derated to "base".
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In general, a scope "one" search is honored, and the scope is derated,
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only when the incoming base is at most one level lower of a target's
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naming context (prior to massaging).
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.LP
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Finally, if the scope is "sub" the incoming base is replaced
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by each target's unmassaged naming context, and the scope
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is not altered.
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.LP
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2b) Consider the above reported scenario with the two servers
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sharing the same naming context:
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.LP
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.RS
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.nf
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database meta
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suffix "\fBdc=foo,dc=com\fP"
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uri "ldap://a.bar.com/\fBdc=foo,dc=com\fP"
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suffixmassage "\fBdc=foo,dc=com\fP" "dc=bar,dc=org"
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uri "ldap://b.foo.com/\fBdc=foo,dc=com\fP"
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suffixmassage "\fBdc=foo,dc=com\fP" "o=Foo,c=US"
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.fi
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.RE
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.LP
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All the previous considerations hold, except that now there is
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no way to unambiguously resolve a DN.
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In this case, all the operations that require an unambiguous target
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selection will fail unless the DN is already cached or a default
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target has been set.
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Practical configurations may result as a combination of all the
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above scenarios.
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.SH ACLs
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Note on ACLs: at present you may add whatever ACL rule you desire
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to to the Meta (and LDAP) backends.
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However, the meaning of an ACL on a proxy may require some
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considerations.
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Two philosophies may be considered:
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.LP
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a) the remote server dictates the permissions; the proxy simply passes
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back what it gets from the remote server.
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.LP
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b) the remote server unveils "everything"; the proxy is responsible
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for protecting data from unauthorized access.
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.LP
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Of course the latter sounds unreasonable, but it is not.
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It is possible to imagine scenarios in which a remote host discloses
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data that can be considered "public" inside an intranet, and a proxy
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that connects it to the internet may impose additional constraints.
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To this purpose, the proxy should be able to comply with all the ACL
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matching criteria that the server supports.
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This has been achieved with regard to all the criteria supported by
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slapd except a special subtle case (please drop me a note if you can
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find other exceptions: <ando@openldap.org>).
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The rule
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.LP
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.RS
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.nf
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access to dn="<dn>" attr=<attr>
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by dnattr=<dnattr> read
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by * none
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.fi
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.RE
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.LP
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cannot be matched iff the attribute that is being requested, <attr>,
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is NOT <dnattr>, and the attribute that determines membership,
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<dnattr>, has not been requested (e.g. in a search)
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.LP
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In fact this ACL is resolved by slapd using the portion of entry it
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retrieved from the remote server without requiring any further
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intervention of the backend, so, if the <dnattr> attribute has not
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been fetched, the match cannot be assessed because the attribute is
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not present, not because no value matches the requirement!
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.LP
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Note on ACLs and attribute mapping: ACLs are applied to the mapped
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attributes; for instance, if the attribute locally known as "foo" is
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mapped to "bar" on a remote server, then local ACLs apply to attribute
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"foo" and are totally unaware of its remote name.
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The remote server will check permissions for "bar", and the local
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server will possibly enforce additional restrictions to "foo".
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.\"
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.\" If this section is moved, also update the reference in
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.\" libraries/librewrite/RATIONALE.
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.\"
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.SH REWRITING
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A string is rewritten according to a set of rules, called a `rewrite
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context'.
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The rules are based on POSIX (''extended'') regular expressions (regex)
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with substring matching; basic variable substitution and map resolution
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of substrings is allowed by specific mechanisms detailed in the following.
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The behavior of pattern matching/substitution can be altered by a set
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of flags.
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.LP
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The underlying concept is to build a lightweight rewrite module
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for the slapd server (initially dedicated to the LDAP backend).
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.SH Passes
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An incoming string is matched against a set of rules.
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Rules are made of a regex match pattern, a substitution pattern
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and a set of actions, described by a set of flags.
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In case of match a string rewriting is performed according to the
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substitution pattern that allows to refer to substrings matched in the
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incoming string.
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The actions, if any, are finally performed.
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The substitution pattern allows map resolution of substrings.
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A map is a generic object that maps a substitution pattern to a value.
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The flags are divided in "Pattern matching Flags" and "Action Flags";
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the former alter the regex match pattern behavior while the latter
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alter the action that is taken after substitution.
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.SH "Pattern Matching Flags"
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.TP
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.B `C'
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honors case in matching (default is case insensitive)
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.TP
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.B `R'
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use POSIX ''basic'' regular expressions (default is ''extended'')
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.TP
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.B `M{n}'
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allow no more than
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.B n
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recursive passes for a specific rule; does not alter the max total count
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of passes, so it can only enforce a stricter limit for a specific rule.
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.SH "Action Flags"
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.TP
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.B `:'
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apply the rule once only (default is recursive)
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.TP
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.B `@'
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stop applying rules in case of match; the current rule is still applied
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recursively; combine with `:' to apply the current rule only once
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and then stop.
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.TP
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.B `#'
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stop current operation if the rule matches, and issue an `unwilling to
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perform' error.
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.TP
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.B `G{n}'
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jump
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.B n
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rules back and forth (watch for loops!).
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Note that `G{1}' is implicit in every rule.
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.TP
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.B `I'
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ignores errors in rule; this means, in case of error, e.g. issued by a
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map, the error is treated as a missed match.
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The `unwilling to perform' is not overridden.
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.TP
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.B `U{n}'
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uses
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.B
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n
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as return code if the rule matches; the flag does not alter the recursive
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behavior of the rule, so, to have it performed only once, it must be used
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in combination with `:', e.g.
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.B `:U{16}'
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returns the value `16' after exactly one execution of the rule, if the
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pattern matches.
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As a consequence, its behavior is equivalent to `@', with the return
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code set to
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.BR n ;
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or, in other words, `@' is equivalent to `U{0}'.
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By convention, the freely available codes are above 16 included;
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the others are reserved.
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.LP
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The ordering of the flags can be significant.
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For instance: `IG{2}' means ignore errors and jump two lines ahead
|
|
both in case of match and in case of error, while `G{2}I' means ignore
|
|
errors, but jump two lines ahead only in case of match.
|
|
.LP
|
|
More flags (mainly Action Flags) will be added as needed.
|
|
.SH "Pattern matching:"
|
|
See
|
|
.BR regex (7)
|
|
and/or
|
|
.BR re_format (7).
|
|
.SH "Substitution Pattern Syntax:"
|
|
Everything starting with `%' requires substitution;
|
|
.LP
|
|
the only obvious exception is `%%', which is left as is;
|
|
.LP
|
|
the basic substitution is `%d', where `d' is a digit;
|
|
0 means the whole string, while 1-9 is a submatch;
|
|
.LP
|
|
a `%' followed by a `{' invokes an advanced substitution.
|
|
The pattern is:
|
|
.LP
|
|
.RS
|
|
`%' `{' [ <op> ] <name> `(' <substitution> `)' `}'
|
|
.RE
|
|
.LP
|
|
where <name> must be a legal name for the map, i.e.
|
|
.LP
|
|
.RS
|
|
.nf
|
|
<name> ::= [a-z][a-z0-9]* (case insensitive)
|
|
<op> ::= `>' `|' `&' `&&' `*' `**' `$'
|
|
.fi
|
|
.RE
|
|
.LP
|
|
and <substitution> must be a legal substitution
|
|
pattern, with no limits on the nesting level.
|
|
.LP
|
|
The operators are:
|
|
.TP
|
|
.B >
|
|
sub context invocation; <name> must be a legal, already defined
|
|
rewrite context name
|
|
.TP
|
|
.B |
|
|
external command invocation; <name> must refer to a legal, already
|
|
defined command name (NOT IMPL.)
|
|
.TP
|
|
.B &
|
|
variable assignment; <name> defines a variable in the running
|
|
operation structure which can be dereferenced later; operator
|
|
.B &
|
|
assigns a variable in the rewrite context scope; operator
|
|
.B &&
|
|
assigns a variable that scopes the entire session, e.g. its value
|
|
can be dereferenced later by other rewrite contexts
|
|
.TP
|
|
.B *
|
|
variable dereferencing; <name> must refer to a variable that is
|
|
defined and assigned for the running operation; operator
|
|
.B *
|
|
dereferences a variable scoping the rewrite context; operator
|
|
.B **
|
|
dereferences a variable scoping the whole session, e.g. the value
|
|
is passed across rewrite contexts
|
|
.TP
|
|
.B $
|
|
parameter dereferencing; <name> must refer to an existing parameter;
|
|
the idea is to make some run-time parameters set by the system
|
|
available to the rewrite engine, as the client host name, the bind DN
|
|
if any, constant parameters initialized at config time, and so on;
|
|
no parameter is currently set by either
|
|
.B back\-ldap
|
|
or
|
|
.BR back\-meta ,
|
|
but constant parameters can be defined in the configuration file
|
|
by using the
|
|
.B rewriteParam
|
|
directive.
|
|
.LP
|
|
Substitution escaping has been delegated to the `%' symbol,
|
|
which is used instead of `\e' in string substitution patterns
|
|
because `\e' is already escaped by slapd's low level parsing routines;
|
|
as a consequence, regex escaping requires two `\e' symbols,
|
|
e.g. `\fB.*\e.foo\e.bar\fP' must be written as `\fB.*\e\e.foo\e\e.bar\fP'.
|
|
.\"
|
|
.\" The symbol can be altered at will by redefining the related macro in
|
|
.\" "rewrite-int.h".
|
|
.\"
|
|
.SH "Rewrite context:"
|
|
A rewrite context is a set of rules which are applied in sequence.
|
|
The basic idea is to have an application initialize a rewrite
|
|
engine (think of Apache's mod_rewrite ...) with a set of rewrite
|
|
contexts; when string rewriting is required, one invokes the
|
|
appropriate rewrite context with the input string and obtains the
|
|
newly rewritten one if no errors occur.
|
|
.LP
|
|
Each basic server operation is associated to a rewrite context;
|
|
they are divided in two main groups: client \-> server and
|
|
server \-> client rewriting.
|
|
.LP
|
|
client -> server:
|
|
.LP
|
|
.RS
|
|
.nf
|
|
(default) if defined and no specific context
|
|
is available
|
|
bindDN bind
|
|
searchBase search
|
|
searchFilter search
|
|
searchFilterAttrDN search
|
|
compareDN compare
|
|
compareAttrDN compare AVA
|
|
addDN add
|
|
addAttrDN add AVA
|
|
modifyDN modify
|
|
modifyAttrDN modify AVA
|
|
modrDN modrdn
|
|
newSuperiorDN modrdn
|
|
deleteDN delete
|
|
exopPasswdDN passwd exop DN if proxy
|
|
.fi
|
|
.RE
|
|
.LP
|
|
server -> client:
|
|
.LP
|
|
.RS
|
|
.nf
|
|
searchResult search (only if defined; no default;
|
|
acts on DN and DN-syntax attributes
|
|
of search results)
|
|
searchAttrDN search AVA
|
|
matchedDN all ops (only if applicable)
|
|
.fi
|
|
.RE
|
|
.LP
|
|
.SH "Basic configuration syntax"
|
|
.TP
|
|
.B rewriteEngine { on | off }
|
|
If `on', the requested rewriting is performed; if `off', no
|
|
rewriting takes place (an easy way to stop rewriting without
|
|
altering too much the configuration file).
|
|
.TP
|
|
.B rewriteContext <context name> "[ alias <aliased context name> ]"
|
|
<Context name> is the name that identifies the context, i.e. the name
|
|
used by the application to refer to the set of rules it contains.
|
|
It is used also to reference sub contexts in string rewriting.
|
|
A context may alias another one.
|
|
In this case the alias context contains no rule, and any reference to
|
|
it will result in accessing the aliased one.
|
|
.TP
|
|
.B rewriteRule "<regex match pattern>" "<substitution pattern>" "[ <flags> ]"
|
|
Determines how a string can be rewritten if a pattern is matched.
|
|
Examples are reported below.
|
|
.SH "Additional configuration syntax:"
|
|
.TP
|
|
.B rewriteMap "<map type>" "<map name>" "[ <map attrs> ]"
|
|
Allows to define a map that transforms substring rewriting into
|
|
something else.
|
|
The map is referenced inside the substitution pattern of a rule.
|
|
.TP
|
|
.B rewriteParam <param name> <param value>
|
|
Sets a value with global scope, that can be dereferenced by the
|
|
command `%{$paramName}'.
|
|
.TP
|
|
.B rewriteMaxPasses <number of passes> [<number of passes per rule>]
|
|
Sets the maximum number of total rewriting passes that can be
|
|
performed in a single rewrite operation (to avoid loops).
|
|
A safe default is set to 100; note that reaching this limit is still
|
|
treated as a success; recursive invocation of rules is simply
|
|
interrupted.
|
|
The count applies to the rewriting operation as a whole, not
|
|
to any single rule; an optional per-rule limit can be set.
|
|
This limit is overridden by setting specific per-rule limits
|
|
with the `M{n}' flag.
|
|
.SH "Configuration examples:"
|
|
.nf
|
|
# set to `off' to disable rewriting
|
|
rewriteEngine on
|
|
|
|
# the rules the "suffixmassage" directive implies
|
|
rewriteEngine on
|
|
# all dataflow from client to server referring to DNs
|
|
rewriteContext default
|
|
rewriteRule "(.*)<virtualnamingcontext>$" "%1<realnamingcontext>" ":"
|
|
# empty filter rule
|
|
rewriteContext searchFilter
|
|
# all dataflow from server to client
|
|
rewriteContext searchResult
|
|
rewriteRule "(.*)<realnamingcontext>$" "%1<virtualnamingcontext>" ":"
|
|
rewriteContext searchAttrDN alias searchResult
|
|
rewriteContext matchedDN alias searchResult
|
|
|
|
# Everything defined here goes into the `default' context.
|
|
# This rule changes the naming context of anything sent
|
|
# to `dc=home,dc=net' to `dc=OpenLDAP, dc=org'
|
|
|
|
rewriteRule "(.*)dc=home,[ ]?dc=net"
|
|
"%1dc=OpenLDAP, dc=org" ":"
|
|
|
|
# since a pretty/normalized DN does not include spaces
|
|
# after rdn separators, e.g. `,', this rule suffices:
|
|
|
|
rewriteRule "(.*)dc=home,dc=net"
|
|
"%1dc=OpenLDAP,dc=org" ":"
|
|
|
|
# Start a new context (ends input of the previous one).
|
|
# This rule adds blanks between DN parts if not present.
|
|
rewriteContext addBlanks
|
|
rewriteRule "(.*),([^ ].*)" "%1, %2"
|
|
|
|
# This one eats blanks
|
|
rewriteContext eatBlanks
|
|
rewriteRule "(.*),[ ](.*)" "%1,%2"
|
|
|
|
# Here control goes back to the default rewrite
|
|
# context; rules are appended to the existing ones.
|
|
# anything that gets here is piped into rule `addBlanks'
|
|
rewriteContext default
|
|
rewriteRule ".*" "%{>addBlanks(%0)}" ":"
|
|
|
|
.\" # Anything with `uid=username' is looked up in
|
|
.\" # /etc/passwd for gecos (I know it's nearly useless,
|
|
.\" # but it is there just as a guideline to implementing
|
|
.\" # custom maps).
|
|
.\" # Note the `I' flag that leaves `uid=username' in place
|
|
.\" # if `username' does not have a valid account, and the
|
|
.\" # `:' that forces the rule to be processed exactly once.
|
|
.\" rewriteContext uid2Gecos
|
|
.\" rewriteRule "(.*)uid=([a-z0-9]+),(.+)"
|
|
.\" "%1cn=%2{xpasswd},%3" "I:"
|
|
.\"
|
|
.\" # Finally, in a bind, if one uses a `uid=username' DN,
|
|
.\" # it is rewritten in `cn=name surname' if possible.
|
|
.\" rewriteContext bindDN
|
|
.\" rewriteRule ".*" "%{>addBlanks(%{>uid2Gecos(%0)})}" ":"
|
|
.\"
|
|
# Rewrite the search base according to `default' rules.
|
|
rewriteContext searchBase alias default
|
|
|
|
# Search results with OpenLDAP DN are rewritten back with
|
|
# `dc=home,dc=net' naming context, with spaces eaten.
|
|
rewriteContext searchResult
|
|
rewriteRule "(.*[^ ]?)[ ]?dc=OpenLDAP,[ ]?dc=org"
|
|
"%{>eatBlanks(%1)}dc=home,dc=net" ":"
|
|
|
|
# Bind with email instead of full DN: we first need
|
|
# an ldap map that turns attributes into a DN (the
|
|
# argument used when invoking the map is appended to
|
|
# the URI and acts as the filter portion)
|
|
rewriteMap ldap attr2dn "ldap://host/dc=my,dc=org?dn?sub"
|
|
|
|
# Then we need to detect DN made up of a single email,
|
|
# e.g. `mail=someone@example.com'; note that the rule
|
|
# in case of match stops rewriting; in case of error,
|
|
# it is ignored. In case we are mapping virtual
|
|
# to real naming contexts, we also need to rewrite
|
|
# regular DNs, because the definition of a bindDn
|
|
# rewrite context overrides the default definition.
|
|
rewriteContext bindDN
|
|
rewriteRule "^mail=[^,]+@[^,]+$" "%{attr2dn(%0)}" ":@I"
|
|
|
|
# This is a rather sophisticated example. It massages a
|
|
# search filter in case who performs the search has
|
|
# administrative privileges. First we need to keep
|
|
# track of the bind DN of the incoming request, which is
|
|
# stored in a variable called `binddn' with session scope,
|
|
# and left in place to allow regular binding:
|
|
rewriteContext bindDN
|
|
rewriteRule ".+" "%{&&binddn(%0)}%0" ":"
|
|
|
|
# A search filter containing `uid=' is rewritten only
|
|
# if an appropriate DN is bound.
|
|
# To do this, in the first rule the bound DN is
|
|
# dereferenced, while the filter is decomposed in a
|
|
# prefix, in the value of the `uid=<arg>' AVA, and
|
|
# in a suffix. A tag `<>' is appended to the DN.
|
|
# If the DN refers to an entry in the `ou=admin' subtree,
|
|
# the filter is rewritten OR-ing the `uid=<arg>' with
|
|
# `cn=<arg>'; otherwise it is left as is. This could be
|
|
# useful, for instance, to allow apache's auth_ldap-1.4
|
|
# module to authenticate users with both `uid' and
|
|
# `cn', but only if the request comes from a possible
|
|
# `cn=Web auth,ou=admin,dc=home,dc=net' user.
|
|
rewriteContext searchFilter
|
|
rewriteRule "(.*\e\e()uid=([a-z0-9_]+)(\e\e).*)"
|
|
"%{**binddn}<>%{&prefix(%1)}%{&arg(%2)}%{&suffix(%3)}"
|
|
":I"
|
|
rewriteRule "[^,]+,ou=admin,dc=home,dc=net"
|
|
"%{*prefix}|(uid=%{*arg})(cn=%{*arg})%{*suffix}" ":@I"
|
|
rewriteRule ".*<>" "%{*prefix}uid=%{*arg}%{*suffix}" ":"
|
|
|
|
# This example shows how to strip unwanted DN-valued
|
|
# attribute values from a search result; the first rule
|
|
# matches DN values below "ou=People,dc=example,dc=com";
|
|
# in case of match the rewriting exits successfully.
|
|
# The second rule matches everything else and causes
|
|
# the value to be rejected.
|
|
rewriteContext searchResult
|
|
rewriteRule ".*,ou=People,dc=example,dc=com" "%0" ":@"
|
|
rewriteRule ".*" "" "#"
|
|
.fi
|
|
.SH "LDAP Proxy resolution (a possible evolution of slapd\-ldap(5)):"
|
|
In case the rewritten DN is an LDAP URI, the operation is initiated
|
|
towards the host[:port] indicated in the uri, if it does not refer
|
|
to the local server.
|
|
E.g.:
|
|
.LP
|
|
.nf
|
|
rewriteRule '^cn=root,.*' '%0' 'G{3}'
|
|
rewriteRule '^cn=[a-l].*' 'ldap://ldap1.my.org/%0' ':@'
|
|
rewriteRule '^cn=[m-z].*' 'ldap://ldap2.my.org/%0' ':@'
|
|
rewriteRule '.*' 'ldap://ldap3.my.org/%0' ':@'
|
|
.fi
|
|
.LP
|
|
(Rule 1 is simply there to illustrate the `G{n}' action; it could have
|
|
been written:
|
|
.LP
|
|
.nf
|
|
rewriteRule '^cn=root,.*' 'ldap://ldap3.my.org/%0' ':@'
|
|
.fi
|
|
.LP
|
|
with the advantage of saving one rewrite pass ...)
|
|
|
|
.SH ACCESS CONTROL
|
|
The
|
|
.B meta
|
|
backend does not honor all ACL semantics as described in
|
|
.BR slapd.access (5).
|
|
In general, access checking is delegated to the remote server(s).
|
|
Only
|
|
.B read (=r)
|
|
access to the
|
|
.B entry
|
|
pseudo-attribute and to the other attribute values of the entries
|
|
returned by the
|
|
.B search
|
|
operation is honored, which is performed by the frontend.
|
|
|
|
.SH PROXY CACHE OVERLAY
|
|
The proxy cache overlay
|
|
allows caching of LDAP search requests (queries) in a local database.
|
|
See
|
|
.BR slapo-pcache (5)
|
|
for details.
|
|
.SH FILES
|
|
.TP
|
|
ETCDIR/slapd.conf
|
|
default slapd configuration file
|
|
.SH SEE ALSO
|
|
.BR slapd.conf (5),
|
|
.BR slapd\-ldap (5),
|
|
.BR slapo\-pcache (5),
|
|
.BR slapd (8),
|
|
.BR regex (7),
|
|
.BR re_format (7).
|
|
.SH AUTHOR
|
|
Pierangelo Masarati, based on back-ldap by Howard Chu
|