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700 lines
26 KiB
Groff
700 lines
26 KiB
Groff
.TH SLAPD-SQL 5 "RELEASEDATE" "OpenLDAP LDVERSION"
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.\" $OpenLDAP$
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.SH NAME
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slapd\-sql \- SQL backend to slapd
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.SH SYNOPSIS
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ETCDIR/slapd.conf
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.SH DESCRIPTION
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The primary purpose of this
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.BR slapd (8)
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backend is to PRESENT information stored in some RDBMS as an LDAP subtree
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without any programming (some SQL and maybe stored procedures can't be
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considered programming, anyway ;).
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.LP
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That is, for example, when you (some ISP) have account information you
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use in an RDBMS, and want to use modern solutions that expect such
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information in LDAP (to authenticate users, make email lookups etc.).
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Or you want to synchronize or distribute information between different
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sites/applications that use RDBMSes and/or LDAP.
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Or whatever else...
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.LP
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It is NOT designed as a general-purpose backend that uses RDBMS instead
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of BerkeleyDB (as the standard BDB backend does), though it can be
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used as such with several limitations.
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You can take a look at
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.B http://www.openldap.org/faq/index.cgi?file=378
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(OpenLDAP FAQ\-O\-Matic/General LDAP FAQ/Directories vs. conventional
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databases) to find out more on this point.
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.LP
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The idea (detailed below) is to use some meta-information to translate
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LDAP queries to SQL queries, leaving relational schema untouched, so
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that old applications can continue using it without any
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modifications.
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This allows SQL and LDAP applications to inter-operate without
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replication, and exchange data as needed.
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.LP
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The SQL backend is designed to be tunable to virtually any relational
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schema without having to change source (through that meta-information
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mentioned).
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Also, it uses ODBC to connect to RDBMSes, and is highly configurable
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for SQL dialects RDBMSes may use, so it may be used for integration
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and distribution of data on different RDBMSes, OSes, hosts etc., in
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other words, in highly heterogeneous environment.
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.LP
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This backend is \fIexperimental\fP.
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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 SQL backend database, which means that
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they must follow a "database sql" line and come before any
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subsequent "backend" or "database" lines.
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Other database options not specific to this backend are described
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in the
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.BR slapd.conf (5)
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manual page.
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.SH DATA SOURCE CONFIGURATION
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.TP
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.B dbname <datasource name>
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The name of the ODBC datasource to use.
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.LP
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.B dbhost <hostname>
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.br
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.B dbpasswd <password>
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.br
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.B dbuser <username>
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.RS
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The three above options are generally unneeded, because this information
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is taken from the datasource specified by the
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.B dbname
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directive.
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They allow to override datasource settings.
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Also, several RDBMS' drivers tend to require explicit passing of user/password,
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even if those are given in datasource (Note:
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.B dbhost
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is currently ignored).
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.RE
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.SH SCOPING CONFIGURATION
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These options specify SQL query templates for scoping searches.
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.TP
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.B subtree_cond <SQL expression>
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Specifies a where-clause template used to form a subtree search condition
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(dn="(.+,)?<dn>$").
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It may differ from one SQL dialect to another (see samples).
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By default, it is constructed based on the knowledge about
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how to normalize DN values (e.g.
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\fB"<upper_func>(ldap_entries.dn) LIKE CONCAT('%',?)"\fP);
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see \fBupper_func\fP, \fBupper_needs_cast\fP, \fBconcat_pattern\fP
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and \fBstrcast_func\fP in "HELPER CONFIGURATION" for details.
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.TP
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.B children_cond <SQL expression>
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Specifies a where-clause template used to form a children search condition
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(dn=".+,<dn>$").
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It may differ from one SQL dialect to another (see samples).
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By default, it is constructed based on the knowledge about
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how to normalize DN values (e.g.
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\fB"<upper_func>(ldap_entries.dn) LIKE CONCAT('%,',?)"\fP);
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see \fBupper_func\fP, \fBupper_needs_cast\fP, \fBconcat_pattern\fP
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and \fBstrcast_func\fP in "HELPER CONFIGURATION" for details.
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.TP
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.B use_subtree_shortcut { YES | no }
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Do not use the subtree condition when the searchBase is the database
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suffix, and the scope is subtree; rather collect all entries.
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.RE
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.SH STATEMENT CONFIGURATION
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These options specify SQL query templates for loading schema mapping
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meta-information, adding and deleting entries to ldap_entries, etc.
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All these and subtree_cond should have the given default values.
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For the current value it is recommended to look at the sources,
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or in the log output when slapd starts with "\-d 5" or greater.
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Note that the parameter number and order must not be changed.
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.TP
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.B oc_query <SQL expression>
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The query that is used to collect the objectClass mapping data
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from table \fIldap_oc_mappings\fP; see "METAINFORMATION USED" for details.
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The default is
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\fB"SELECT id, name, keytbl, keycol, create_proc, delete_proc, expect_return
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FROM ldap_oc_mappings"\fP.
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.TP
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.B at_query <SQL expression>
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The query that is used to collect the attributeType mapping data
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from table \fIldap_attr_mappings\fP; see "METAINFORMATION USED" for details.
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The default is
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\fB"SELECT name, sel_expr, from_tbls, join_where, add_proc, delete_proc,
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param_order, expect_return FROM ldap_attr_mappings WHERE oc_map_id=?"\fP.
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.TP
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.B id_query <SQL expression>
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The query that is used to map a DN to an entry
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in table \fIldap_entries\fP; see "METAINFORMATION USED" for details.
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The default is
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\fB"SELECT id,keyval,oc_map_id,dn FROM ldap_entries WHERE <DN match expr>"\fP,
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where \fB<DN match expr>\fP is constructed based on the knowledge about
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how to normalize DN values (e.g. \fB"dn=?"\fP if no means to uppercase
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strings are available; typically, \fB"<upper_func>(dn)=?"\fP is used);
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see \fBupper_func\fP, \fBupper_needs_cast\fP, \fBconcat_pattern\fP
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and \fBstrcast_func\fP in "HELPER CONFIGURATION" for details.
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.TP
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.B insentry_stmt <SQL expression>
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The statement that is used to insert a new entry
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in table \fIldap_entries\fP; see "METAINFORMATION USED" for details.
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The default is
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\fB"INSERT INTO ldap_entries (dn, oc_map_id, parent, keyval) VALUES
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(?, ?, ?, ?)"\fP.
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.TP
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.B delentry_stmt <SQL expression>
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The statement that is used to delete an existing entry
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from table \fIldap_entries\fP; see "METAINFORMATION USED" for details.
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The default is
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\fB"DELETE FROM ldap_entries WHERE id=?"\fP.
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.TP
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.B delobjclasses_stmt <SQL expression>
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The statement that is used to delete an existing entry's ID
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from table \fIldap_objclasses\fP; see "METAINFORMATION USED" for details.
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The default is
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\fB"DELETE FROM ldap_entry_objclasses WHERE entry_id=?"\fP.
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.RE
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.SH HELPER CONFIGURATION
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These statements are used to modify the default behavior of the backend
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according to issues of the dialect of the RDBMS.
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The first options essentially refer to string and DN normalization
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when building filters.
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LDAP normalization is more than upper- (or lower-)casing everything;
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however, as a reasonable trade-off, for case-sensitive RDBMSes the backend
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can be instructed to uppercase strings and DNs by providing
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the \fBupper_func\fP directive.
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Some RDBMSes, to use functions on arbitrary data types, e.g. string
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constants, requires a cast, which is triggered
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by the \fBupper_needs_cast\fP directive.
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If required, a string cast function can be provided as well,
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by using the \fBstrcast_func\fP directive.
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Finally, a custom string concatenation pattern may be required;
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it is provided by the \fBconcat_pattern\fP directive.
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.TP
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.B upper_func <SQL function name>
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Specifies the name of a function that converts a given value to uppercase.
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This is used for case insensitive matching when the RDBMS is case sensitive.
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It may differ from one SQL dialect to another (e.g. \fBUCASE\fP, \fBUPPER\fP
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or whatever; see samples). By default, none is used, i.e. strings are not
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uppercased, so matches may be case sensitive.
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.TP
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.B upper_needs_cast { NO | yes }
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Set this directive to
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.B yes
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if
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.B upper_func
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needs an explicit cast when applied to literal strings.
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A cast in the form
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.B CAST (<arg> AS VARCHAR(<max DN length>))
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is used, where
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.B <max DN length>
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is builtin in back-sql; see macro
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.B BACKSQL_MAX_DN_LEN
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(currently 255; note that slapd's builtin limit, in macro
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.BR SLAP_LDAPDN_MAXLEN ,
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is set to 8192).
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This is \fIexperimental\fP and may change in future releases.
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.TP
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.B strcast_func <SQL function name>
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Specifies the name of a function that converts a given value to a string
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for appropriate ordering. This is used in "SELECT DISTINCT" statements
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for strongly typed RDBMSes with little implicit casting (like PostgreSQL),
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when a literal string is specified.
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This is \fIexperimental\fP and may change in future releases.
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.TP
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.B concat_pattern <pattern>
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This statement defines the
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.B pattern
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that is used to concatenate strings. The
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.B pattern
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MUST contain two question marks, '?', that will be replaced
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by the two strings that must be concatenated. The default value is
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.BR "CONCAT(?,?)";
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a form that is known to be highly portable (IBM db2, PostgreSQL) is
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.BR "?||?",
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but an explicit cast may be required when operating on literal strings:
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.BR "CAST(?||? AS VARCHAR(<length>))".
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On some RDBMSes (IBM db2, MSSQL) the form
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.B "?+?"
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is known to work as well.
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Carefully check the documentation of your RDBMS or stay with the examples
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for supported ones.
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This is \fIexperimental\fP and may change in future releases.
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.TP
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.B aliasing_keyword <string>
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Define the aliasing keyword. Some RDBMSes use the word "\fIAS\fP"
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(the default), others don't use any.
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.TP
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.B aliasing_quote <string>
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Define the quoting char of the aliasing keyword. Some RDBMSes
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don't require any (the default), others may require single
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or double quotes.
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.TP
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.B has_ldapinfo_dn_ru { NO | yes }
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Explicitly inform the backend whether the dn_ru column
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(DN in reverse uppercased form) is present in table \fIldap_entries\fP.
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Overrides automatic check (this is required, for instance,
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by PostgreSQL/unixODBC).
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This is \fIexperimental\fP and may change in future releases.
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.TP
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.B fail_if_no_mapping { NO | yes }
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When set to
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.B yes
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it forces \fIattribute\fP write operations to fail if no appropriate
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mapping between LDAP attributes and SQL data is available.
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The default behavior is to ignore those changes that cannot be mapped.
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It has no impact on objectClass mapping, i.e. if the
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.I structuralObjectClass
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of an entry cannot be mapped to SQL by looking up its name
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in ldap_oc_mappings, an
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.I add
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operation will fail regardless of the
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.B fail_if_no_mapping
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switch; see section "METAINFORMATION USED" for details.
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This is \fIexperimental\fP and may change in future releases.
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.TP
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.B allow_orphans { NO | yes }
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When set to
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.B yes
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orphaned entries (i.e. without the parent entry in the database)
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can be added. This option should be used with care, possibly
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in conjunction with some special rule on the RDBMS side that
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dynamically creates the missing parent.
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.TP
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.B baseObject [ <filename> ]
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Instructs the database to create and manage an in-memory baseObject
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entry instead of looking for one in the RDBMS.
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If the (optional)
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.B <filename>
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argument is given, the entry is read from that file in
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.BR LDIF (5)
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format; otherwise, an entry with objectClass \fBextensibleObject\fP
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is created based on the contents of the RDN of the \fIbaseObject\fP.
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This is particularly useful when \fIldap_entries\fP
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information is stored in a view rather than in a table, and
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.B union
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is not supported for views, so that the view can only specify
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one rule to compute the entry structure for one objectClass.
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This topic is discussed further in section "METAINFORMATION USED".
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This is \fIexperimental\fP and may change in future releases.
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.TP
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.B create_needs_select { NO | yes }
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Instructs the database whether or not entry creation
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in table \fIldap_entries\fP needs a subsequent select to collect
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the automatically assigned ID, instead of being returned
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by a stored procedure.
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.LP
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.B fetch_attrs <attrlist>
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.br
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.B fetch_all_attrs { NO | yes }
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.RS
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The first statement allows to provide a list of attributes that
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must always be fetched in addition to those requested by any specific
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operation, because they are required for the proper usage of the
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backend. For instance, all attributes used in ACLs should be listed
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here. The second statement is a shortcut to require all attributes
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to be always loaded. Note that the dynamically generated attributes,
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e.g. \fIhasSubordinates\fP, \fIentryDN\fP and other implementation
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dependent attributes are \fBNOT\fP generated at this point, for
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consistency with the rest of slapd. This may change in the future.
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.RE
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.TP
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.B check_schema { YES | no }
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Instructs the database to check schema adherence of entries after
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modifications, and structural objectClass chain when entries are built.
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By default it is set to
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.BR yes .
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.TP
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.B sqllayer <name> [...]
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Loads the layer \fB<name>\fP onto a stack of helpers that are used
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to map DNs from LDAP to SQL representation and vice-versa.
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Subsequent args are passed to the layer configuration routine.
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This is \fIhighly experimental\fP and should be used with extreme care.
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The API of the layers is not frozen yet, so it is unpublished.
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.TP
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.B autocommit { NO | yes }
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Activates autocommit; by default, it is off.
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.SH METAINFORMATION USED
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.LP
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Almost everything mentioned later is illustrated in examples located
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in the
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.B servers/slapd/back\-sql/rdbms_depend/
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directory in the OpenLDAP source tree, and contains scripts for
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generating sample database for Oracle, MS SQL Server, mySQL and more
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(including PostgreSQL and IBM db2).
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.LP
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The first thing that one must arrange is what set of LDAP
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object classes can present your RDBMS information.
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.LP
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The easiest way is to create an objectClass for each entity you had in
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ER-diagram when designing your relational schema.
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Any relational schema, no matter how normalized it is, was designed
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after some model of your application's domain (for instance, accounts,
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services etc. in ISP), and is used in terms of its entities, not just
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tables of normalized schema.
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It means that for every attribute of every such instance there is an
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effective SQL query that loads its values.
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.LP
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Also you might want your object classes to conform to some of the standard
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schemas like inetOrgPerson etc.
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.LP
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Nevertheless, when you think it out, we must define a way to translate
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LDAP operation requests to (a series of) SQL queries.
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Let us deal with the SEARCH operation.
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.LP
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Example:
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Let's suppose that we store information about persons working in our
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organization in two tables:
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.LP
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.nf
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PERSONS PHONES
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---------- -------------
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id integer id integer
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first_name varchar pers_id integer references persons(id)
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last_name varchar phone
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middle_name varchar
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...
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.fi
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.LP
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(PHONES contains telephone numbers associated with persons).
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A person can have several numbers, then PHONES contains several
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records with corresponding pers_id, or no numbers (and no records in
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PHONES with such pers_id).
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An LDAP objectclass to present such information could look like this:
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.LP
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.nf
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person
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-------
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MUST cn
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MAY telephoneNumber $ firstName $ lastName
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...
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.fi
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.LP
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To fetch all values for cn attribute given person ID, we construct the
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query:
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.LP
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.nf
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SELECT CONCAT(persons.first_name,' ',persons.last_name)
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AS cn FROM persons WHERE persons.id=?
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.fi
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.LP
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for telephoneNumber we can use:
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.LP
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.nf
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SELECT phones.phone AS telephoneNumber FROM persons,phones
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WHERE persons.id=phones.pers_id AND persons.id=?
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.fi
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.LP
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If we wanted to service LDAP requests with filters like
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(telephoneNumber=123*), we would construct something like:
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.LP
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.nf
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SELECT ... FROM persons,phones
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WHERE persons.id=phones.pers_id
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AND persons.id=?
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AND phones.phone like '%1%2%3%'
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.fi
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.LP
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(note how the telephoneNumber match is expanded in multiple wildcards
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to account for interspersed ininfluential chars like spaces, dashes
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and so; this occurs by design because telephoneNumber is defined after
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a specially recognized syntax).
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So, if we had information about what tables contain values for each
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attribute, how to join these tables and arrange these values, we could
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try to automatically generate such statements, and translate search
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filters to SQL WHERE clauses.
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.LP
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To store such information, we add three more tables to our schema
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and fill it with data (see samples):
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.LP
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.nf
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ldap_oc_mappings (some columns are not listed for clarity)
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---------------
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id=1
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name="person"
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keytbl="persons"
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keycol="id"
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.fi
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.LP
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This table defines a mapping between objectclass (its name held in the
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"name" column), and a table that holds the primary key for corresponding
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entities.
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For instance, in our example, the person entity, which we are trying
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to present as "person" objectclass, resides in two tables (persons and
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phones), and is identified by the persons.id column (that we will call
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the primary key for this entity).
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Keytbl and keycol thus contain "persons" (name of the table), and "id"
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(name of the column).
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.LP
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.nf
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ldap_attr_mappings (some columns are not listed for clarity)
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-----------
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id=1
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oc_map_id=1
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name="cn"
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sel_expr="CONCAT(persons.first_name,' ',persons.last_name)"
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from_tbls="persons"
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join_where=NULL
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************
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id=<n>
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oc_map_id=1
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name="telephoneNumber"
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sel_expr="phones.phone"
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from_tbls="persons,phones"
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join_where="phones.pers_id=persons.id"
|
|
.fi
|
|
.LP
|
|
This table defines mappings between LDAP attributes and SQL queries
|
|
that load their values.
|
|
Note that, unlike LDAP schema, these are not
|
|
.B attribute types
|
|
- the attribute "cn" for "person" objectclass can
|
|
have its values in different tables than "cn" for some other objectclass,
|
|
so attribute mappings depend on objectclass mappings (unlike attribute
|
|
types in LDAP schema, which are indifferent to objectclasses).
|
|
Thus, we have oc_map_id column with link to oc_mappings table.
|
|
.LP
|
|
Now we cut the SQL query that loads values for a given attribute into 3 parts.
|
|
First goes into sel_expr column - this is the expression we had
|
|
between SELECT and FROM keywords, which defines WHAT to load.
|
|
Next is table list - text between FROM and WHERE keywords.
|
|
It may contain aliases for convenience (see examples).
|
|
The last is part of the where clause, which (if it exists at all) expresses the
|
|
condition for joining the table containing values with the table
|
|
containing the primary key (foreign key equality and such).
|
|
If values are in the same table as the primary key, then this column is
|
|
left NULL (as for cn attribute above).
|
|
.LP
|
|
Having this information in parts, we are able to not only construct
|
|
queries that load attribute values by id of entry (for this we could
|
|
store SQL query as a whole), but to construct queries that load id's
|
|
of objects that correspond to a given search filter (or at least part of
|
|
it).
|
|
See below for examples.
|
|
.LP
|
|
.nf
|
|
ldap_entries
|
|
------------
|
|
id=1
|
|
dn=<dn you choose>
|
|
oc_map_id=...
|
|
parent=<parent record id>
|
|
keyval=<value of primary key>
|
|
.fi
|
|
.LP
|
|
This table defines mappings between DNs of entries in your LDAP tree,
|
|
and values of primary keys for corresponding relational data.
|
|
It has recursive structure (parent column references id column of the
|
|
same table), which allows you to add any tree structure(s) to your
|
|
flat relational data.
|
|
Having id of objectclass mapping, we can determine table and column
|
|
for primary key, and keyval stores value of it, thus defining the exact
|
|
tuple corresponding to the LDAP entry with this DN.
|
|
.LP
|
|
Note that such design (see exact SQL table creation query) implies one
|
|
important constraint - the key must be an integer.
|
|
But all that I know about well-designed schemas makes me think that it's
|
|
not very narrow ;) If anyone needs support for different types for
|
|
keys - he may want to write a patch, and submit it to OpenLDAP ITS,
|
|
then I'll include it.
|
|
.LP
|
|
Also, several users complained that they don't really need very
|
|
structured trees, and they don't want to update one more table every
|
|
time they add or delete an instance in the relational schema.
|
|
Those people can use a view instead of a real table for ldap_entries, something
|
|
like this (by Robin Elfrink):
|
|
.LP
|
|
.nf
|
|
CREATE VIEW ldap_entries (id, dn, oc_map_id, parent, keyval)
|
|
AS
|
|
SELECT 0, UPPER('o=MyCompany,c=NL'),
|
|
3, 0, 'baseObject' FROM unixusers WHERE userid='root'
|
|
UNION
|
|
SELECT (1000000000+userid),
|
|
UPPER(CONCAT(CONCAT('cn=',gecos),',o=MyCompany,c=NL')),
|
|
1, 0, userid FROM unixusers
|
|
UNION
|
|
SELECT (2000000000+groupnummer),
|
|
UPPER(CONCAT(CONCAT('cn=',groupnaam),',o=MyCompany,c=NL')),
|
|
2, 0, groupnummer FROM groups;
|
|
.fi
|
|
|
|
.LP
|
|
If your RDBMS does not support
|
|
.B unions
|
|
in views, only one objectClass can be mapped in
|
|
.BR ldap_entries ,
|
|
and the baseObject cannot be created; in this case, see the
|
|
.B baseObject
|
|
directive for a possible workaround.
|
|
|
|
.LP
|
|
.SH TYPICAL SQL BACKEND OPERATION
|
|
Having meta-information loaded, the SQL backend uses these tables to
|
|
determine a set of primary keys of candidates (depending on search
|
|
scope and filter).
|
|
It tries to do it for each objectclass registered in ldap_objclasses.
|
|
.LP
|
|
Example:
|
|
for our query with filter (telephoneNumber=123*) we would get the following
|
|
query generated (which loads candidate IDs)
|
|
.LP
|
|
.nf
|
|
SELECT ldap_entries.id,persons.id, 'person' AS objectClass,
|
|
ldap_entries.dn AS dn
|
|
FROM ldap_entries,persons,phones
|
|
WHERE persons.id=ldap_entries.keyval
|
|
AND ldap_entries.objclass=?
|
|
AND ldap_entries.parent=?
|
|
AND phones.pers_id=persons.id
|
|
AND (phones.phone LIKE '%1%2%3%')
|
|
.fi
|
|
.LP
|
|
(for ONELEVEL search)
|
|
or "... AND dn=?" (for BASE search)
|
|
or "... AND dn LIKE '%?'" (for SUBTREE)
|
|
.LP
|
|
Then, for each candidate, we load the requested attributes using
|
|
per-attribute queries like
|
|
.LP
|
|
.nf
|
|
SELECT phones.phone AS telephoneNumber
|
|
FROM persons,phones
|
|
WHERE persons.id=? AND phones.pers_id=persons.id
|
|
.fi
|
|
.LP
|
|
Then, we use test_filter() from the frontend API to test the entry for a full
|
|
LDAP search filter match (since we cannot effectively make sense of
|
|
SYNTAX of corresponding LDAP schema attribute, we translate the filter
|
|
into the most relaxed SQL condition to filter candidates), and send it to
|
|
the user.
|
|
.LP
|
|
ADD, DELETE, MODIFY and MODRDN operations are also performed on per-attribute
|
|
meta-information (add_proc etc.).
|
|
In those fields one can specify an SQL statement or stored procedure
|
|
call which can add, or delete given values of a given attribute, using
|
|
the given entry keyval (see examples -- mostly PostgreSQL, ORACLE and MSSQL
|
|
- since as of this writing there are no stored procs in MySQL).
|
|
.LP
|
|
We just add more columns to ldap_oc_mappings and ldap_attr_mappings, holding
|
|
statements to execute (like create_proc, add_proc, del_proc etc.), and
|
|
flags governing the order of parameters passed to those statements.
|
|
Please see samples to find out what are the parameters passed, and other
|
|
information on this matter - they are self-explanatory for those familiar
|
|
with the concepts expressed above.
|
|
.LP
|
|
.SH COMMON TECHNIQUES
|
|
First of all, let's recall that among other major differences to the
|
|
complete LDAP data model, the above illustrated concept does not directly
|
|
support such features as multiple objectclasses per entry, and referrals.
|
|
Fortunately, they are easy to adopt in this scheme.
|
|
The SQL backend requires that one more table is added to the schema:
|
|
ldap_entry_objectclasses(entry_id,oc_name).
|
|
.LP
|
|
That table contains any number of objectclass names that corresponding
|
|
entries will possess, in addition to that mentioned in mapping.
|
|
The SQL backend automatically adds attribute mapping for the "objectclass"
|
|
attribute to each objectclass mapping that loads values from this table.
|
|
So, you may, for instance, have a mapping for inetOrgPerson, and use it
|
|
for queries for "person" objectclass...
|
|
.LP
|
|
Referrals used to be implemented in a loose manner by adding an extra
|
|
table that allowed any entry to host a "ref" attribute, along with
|
|
a "referral" extra objectClass in table ldap_entry_objclasses.
|
|
In the current implementation, referrals are treated like any other
|
|
user-defined schema, since "referral" is a structural objectclass.
|
|
The suggested practice is to define a "referral" entry in ldap_oc_mappings,
|
|
holding a naming attribute, e.g. "ou" or "cn", a "ref" attribute,
|
|
containing the url; in case multiple referrals per entry are needed,
|
|
a separate table for urls can be created, where urls are mapped
|
|
to the respective entries.
|
|
The use of the naming attribute usually requires to add
|
|
an "extensibleObject" value to ldap_entry_objclasses.
|
|
|
|
.LP
|
|
.SH CAVEATS
|
|
As previously stated, this backend should not be considered
|
|
a replacement of other data storage backends, but rather a gateway
|
|
to existing RDBMS storages that need to be published in LDAP form.
|
|
.LP
|
|
The \fBhasSubordintes\fP operational attribute is honored by back-sql
|
|
in search results and in compare operations; it is partially honored
|
|
also in filtering. Owing to design limitations, a (brain-dead?) filter
|
|
of the form
|
|
\fB(!(hasSubordinates=TRUE))\fP
|
|
will give no results instead of returning all the leaf entries, because
|
|
it actually expands into \fB... AND NOT (1=1)\fP.
|
|
If you need to find all the leaf entries, please use
|
|
\fB(hasSubordinates=FALSE)\fP
|
|
instead.
|
|
.LP
|
|
A directoryString value of the form "__First___Last_"
|
|
(where underscores mean spaces, ASCII 0x20 char) corresponds
|
|
to its prettified counterpart "First_Last"; this is not currently
|
|
honored by back-sql if non-prettified data is written via RDBMS;
|
|
when non-prettified data is written through back-sql, the prettified
|
|
values are actually used instead.
|
|
|
|
.LP
|
|
.SH BUGS
|
|
When the
|
|
.B ldap_entry_objclasses
|
|
table is empty, filters on the
|
|
.B objectClass
|
|
attribute erroneously result in no candidates.
|
|
A workaround consists in adding at least one row to that table,
|
|
no matter if valid or not.
|
|
|
|
.LP
|
|
.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 EXAMPLES
|
|
There are example SQL modules in the slapd/back\-sql/rdbms_depend/
|
|
directory in the OpenLDAP source tree.
|
|
.SH ACCESS CONTROL
|
|
The
|
|
.B sql
|
|
backend honors access control semantics as indicated in
|
|
.BR slapd.access (5)
|
|
(including the
|
|
.B disclose
|
|
access privilege when enabled at compile time).
|
|
.SH FILES
|
|
|
|
.TP
|
|
ETCDIR/slapd.conf
|
|
default slapd configuration file
|
|
.SH SEE ALSO
|
|
.BR slapd.conf (5),
|
|
.BR slapd (8).
|