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<!DOCTYPE html PUBLIC "-//W3C//DTD XHTML 1.0 Transitional//EN" "http://www.w3.org/TR/xhtml1/DTD/xhtml1-transitional.dtd"><html xmlns="http://www.w3.org/1999/xhtml"><head><meta http-equiv="Content-Type" content="text/html; charset=UTF-8" /><title>5.4. Constraints</title><link rel="stylesheet" type="text/css" href="stylesheet.css" /><link rev="made" href="pgsql-docs@lists.postgresql.org" /><meta name="generator" content="DocBook XSL Stylesheets Vsnapshot" /><link rel="prev" href="ddl-generated-columns.html" title="5.3. Generated Columns" /><link rel="next" href="ddl-system-columns.html" title="5.5. System Columns" /></head><body id="docContent" class="container-fluid col-10"><div class="navheader"><table width="100%" summary="Navigation header"><tr><th colspan="5" align="center">5.4. Constraints</th></tr><tr><td width="10%" align="left"><a accesskey="p" href="ddl-generated-columns.html" title="5.3. Generated Columns">Prev</a> </td><td width="10%" align="left"><a accesskey="u" href="ddl.html" title="Chapter 5. Data Definition">Up</a></td><th width="60%" align="center">Chapter 5. Data Definition</th><td width="10%" align="right"><a accesskey="h" href="index.html" title="PostgreSQL 15.6 Documentation">Home</a></td><td width="10%" align="right"> <a accesskey="n" href="ddl-system-columns.html" title="5.5. System Columns">Next</a></td></tr></table><hr /></div><div class="sect1" id="DDL-CONSTRAINTS"><div class="titlepage"><div><div><h2 class="title" style="clear: both">5.4. Constraints</h2></div></div></div><div class="toc"><dl class="toc"><dt><span class="sect2"><a href="ddl-constraints.html#DDL-CONSTRAINTS-CHECK-CONSTRAINTS">5.4.1. Check Constraints</a></span></dt><dt><span class="sect2"><a href="ddl-constraints.html#id-1.5.4.6.6">5.4.2. Not-Null Constraints</a></span></dt><dt><span class="sect2"><a href="ddl-constraints.html#DDL-CONSTRAINTS-UNIQUE-CONSTRAINTS">5.4.3. Unique Constraints</a></span></dt><dt><span class="sect2"><a href="ddl-constraints.html#DDL-CONSTRAINTS-PRIMARY-KEYS">5.4.4. Primary Keys</a></span></dt><dt><span class="sect2"><a href="ddl-constraints.html#DDL-CONSTRAINTS-FK">5.4.5. Foreign Keys</a></span></dt><dt><span class="sect2"><a href="ddl-constraints.html#DDL-CONSTRAINTS-EXCLUSION">5.4.6. Exclusion Constraints</a></span></dt></dl></div><a id="id-1.5.4.6.2" class="indexterm"></a><p>
   Data types are a way to limit the kind of data that can be stored
   in a table.  For many applications, however, the constraint they
   provide is too coarse.  For example, a column containing a product
   price should probably only accept positive values.  But there is no
   standard data type that accepts only positive numbers.  Another issue is
   that you might want to constrain column data with respect to other
   columns or rows.  For example, in a table containing product
   information, there should be only one row for each product number.
  </p><p>
   To that end, SQL allows you to define constraints on columns and
   tables.  Constraints give you as much control over the data in your
   tables as you wish.  If a user attempts to store data in a column
   that would violate a constraint, an error is raised.  This applies
   even if the value came from the default value definition.
  </p><div class="sect2" id="DDL-CONSTRAINTS-CHECK-CONSTRAINTS"><div class="titlepage"><div><div><h3 class="title">5.4.1. Check Constraints</h3></div></div></div><a id="id-1.5.4.6.5.2" class="indexterm"></a><a id="id-1.5.4.6.5.3" class="indexterm"></a><p>
    A check constraint is the most generic constraint type.  It allows
    you to specify that the value in a certain column must satisfy a
    Boolean (truth-value) expression.  For instance, to require positive
    product prices, you could use:
</p><pre class="programlisting">
CREATE TABLE products (
    product_no integer,
    name text,
    price numeric <span class="emphasis"><strong>CHECK (price &gt; 0)</strong></span>
);
</pre><p>
   </p><p>
    As you see, the constraint definition comes after the data type,
    just like default value definitions.  Default values and
    constraints can be listed in any order.  A check constraint
    consists of the key word <code class="literal">CHECK</code> followed by an
    expression in parentheses.  The check constraint expression should
    involve the column thus constrained, otherwise the constraint
    would not make too much sense.
   </p><a id="id-1.5.4.6.5.6" class="indexterm"></a><p>
    You can also give the constraint a separate name.  This clarifies
    error messages and allows you to refer to the constraint when you
    need to change it.  The syntax is:
</p><pre class="programlisting">
CREATE TABLE products (
    product_no integer,
    name text,
    price numeric <span class="emphasis"><strong>CONSTRAINT positive_price</strong></span> CHECK (price &gt; 0)
);
</pre><p>
    So, to specify a named constraint, use the key word
    <code class="literal">CONSTRAINT</code> followed by an identifier followed
    by the constraint definition.  (If you don't specify a constraint
    name in this way, the system chooses a name for you.)
   </p><p>
    A check constraint can also refer to several columns.  Say you
    store a regular price and a discounted price, and you want to
    ensure that the discounted price is lower than the regular price:
</p><pre class="programlisting">
CREATE TABLE products (
    product_no integer,
    name text,
    price numeric CHECK (price &gt; 0),
    discounted_price numeric CHECK (discounted_price &gt; 0),
    <span class="emphasis"><strong>CHECK (price &gt; discounted_price)</strong></span>
);
</pre><p>
   </p><p>
    The first two constraints should look familiar.  The third one
    uses a new syntax.  It is not attached to a particular column,
    instead it appears as a separate item in the comma-separated
    column list.  Column definitions and these constraint
    definitions can be listed in mixed order.
   </p><p>
    We say that the first two constraints are column constraints, whereas the
    third one is a table constraint because it is written separately
    from any one column definition.  Column constraints can also be
    written as table constraints, while the reverse is not necessarily
    possible, since a column constraint is supposed to refer to only the
    column it is attached to.  (<span class="productname">PostgreSQL</span> doesn't
    enforce that rule, but you should follow it if you want your table
    definitions to work with other database systems.)  The above example could
    also be written as:
</p><pre class="programlisting">
CREATE TABLE products (
    product_no integer,
    name text,
    price numeric,
    CHECK (price &gt; 0),
    discounted_price numeric,
    CHECK (discounted_price &gt; 0),
    CHECK (price &gt; discounted_price)
);
</pre><p>
    or even:
</p><pre class="programlisting">
CREATE TABLE products (
    product_no integer,
    name text,
    price numeric CHECK (price &gt; 0),
    discounted_price numeric,
    CHECK (discounted_price &gt; 0 AND price &gt; discounted_price)
);
</pre><p>
    It's a matter of taste.
   </p><p>
    Names can be assigned to table constraints in the same way as
    column constraints:
</p><pre class="programlisting">
CREATE TABLE products (
    product_no integer,
    name text,
    price numeric,
    CHECK (price &gt; 0),
    discounted_price numeric,
    CHECK (discounted_price &gt; 0),
    <span class="emphasis"><strong>CONSTRAINT valid_discount</strong></span> CHECK (price &gt; discounted_price)
);
</pre><p>
   </p><a id="id-1.5.4.6.5.12" class="indexterm"></a><p>
    It should be noted that a check constraint is satisfied if the
    check expression evaluates to true or the null value.  Since most
    expressions will evaluate to the null value if any operand is null,
    they will not prevent null values in the constrained columns.  To
    ensure that a column does not contain null values, the not-null
    constraint described in the next section can be used.
   </p><div class="note"><h3 class="title">Note</h3><p>
     <span class="productname">PostgreSQL</span> does not support
     <code class="literal">CHECK</code> constraints that reference table data other than
     the new or updated row being checked.  While a <code class="literal">CHECK</code>
     constraint that violates this rule may appear to work in simple
     tests, it cannot guarantee that the database will not reach a state
     in which the constraint condition is false (due to subsequent changes
     of the other row(s) involved).  This would cause a database dump and
     restore to fail.  The restore could fail even when the complete
     database state is consistent with the constraint, due to rows not
     being loaded in an order that will satisfy the constraint.  If
     possible, use <code class="literal">UNIQUE</code>, <code class="literal">EXCLUDE</code>,
     or <code class="literal">FOREIGN KEY</code> constraints to express
     cross-row and cross-table restrictions.
    </p><p>
     If what you desire is a one-time check against other rows at row
     insertion, rather than a continuously-maintained consistency
     guarantee, a custom <a class="link" href="triggers.html" title="Chapter 39. Triggers">trigger</a> can be used
     to implement that.  (This approach avoids the dump/restore problem because
     <span class="application">pg_dump</span> does not reinstall triggers until after
     restoring data, so that the check will not be enforced during a
     dump/restore.)
    </p></div><div class="note"><h3 class="title">Note</h3><p>
     <span class="productname">PostgreSQL</span> assumes that
     <code class="literal">CHECK</code> constraints' conditions are immutable, that
     is, they will always give the same result for the same input row.
     This assumption is what justifies examining <code class="literal">CHECK</code>
     constraints only when rows are inserted or updated, and not at other
     times.  (The warning above about not referencing other table data is
     really a special case of this restriction.)
    </p><p>
     An example of a common way to break this assumption is to reference a
     user-defined function in a <code class="literal">CHECK</code> expression, and
     then change the behavior of that
     function.  <span class="productname">PostgreSQL</span> does not disallow
     that, but it will not notice if there are rows in the table that now
     violate the <code class="literal">CHECK</code> constraint. That would cause a
     subsequent database dump and restore to fail.
     The recommended way to handle such a change is to drop the constraint
     (using <code class="command">ALTER TABLE</code>), adjust the function definition,
     and re-add the constraint, thereby rechecking it against all table rows.
    </p></div></div><div class="sect2" id="id-1.5.4.6.6"><div class="titlepage"><div><div><h3 class="title">5.4.2. Not-Null Constraints</h3></div></div></div><a id="id-1.5.4.6.6.2" class="indexterm"></a><a id="id-1.5.4.6.6.3" class="indexterm"></a><p>
    A not-null constraint simply specifies that a column must not
    assume the null value.  A syntax example:
</p><pre class="programlisting">
CREATE TABLE products (
    product_no integer <span class="emphasis"><strong>NOT NULL</strong></span>,
    name text <span class="emphasis"><strong>NOT NULL</strong></span>,
    price numeric
);
</pre><p>
   </p><p>
    A not-null constraint is always written as a column constraint.  A
    not-null constraint is functionally equivalent to creating a check
    constraint <code class="literal">CHECK (<em class="replaceable"><code>column_name</code></em>
    IS NOT NULL)</code>, but in
    <span class="productname">PostgreSQL</span> creating an explicit
    not-null constraint is more efficient.  The drawback is that you
    cannot give explicit names to not-null constraints created this
    way.
   </p><p>
    Of course, a column can have more than one constraint.  Just write
    the constraints one after another:
</p><pre class="programlisting">
CREATE TABLE products (
    product_no integer NOT NULL,
    name text NOT NULL,
    price numeric NOT NULL CHECK (price &gt; 0)
);
</pre><p>
    The order doesn't matter.  It does not necessarily determine in which
    order the constraints are checked.
   </p><p>
    The <code class="literal">NOT NULL</code> constraint has an inverse: the
    <code class="literal">NULL</code> constraint.  This does not mean that the
    column must be null, which would surely be useless.  Instead, this
    simply selects the default behavior that the column might be null.
    The <code class="literal">NULL</code> constraint is not present in the SQL
    standard and should not be used in portable applications.  (It was
    only added to <span class="productname">PostgreSQL</span> to be
    compatible with some other database systems.)  Some users, however,
    like it because it makes it easy to toggle the constraint in a
    script file.  For example, you could start with:
</p><pre class="programlisting">
CREATE TABLE products (
    product_no integer NULL,
    name text NULL,
    price numeric NULL
);
</pre><p>
    and then insert the <code class="literal">NOT</code> key word where desired.
   </p><div class="tip"><h3 class="title">Tip</h3><p>
     In most database designs the majority of columns should be marked
     not null.
    </p></div></div><div class="sect2" id="DDL-CONSTRAINTS-UNIQUE-CONSTRAINTS"><div class="titlepage"><div><div><h3 class="title">5.4.3. Unique Constraints</h3></div></div></div><a id="id-1.5.4.6.7.2" class="indexterm"></a><a id="id-1.5.4.6.7.3" class="indexterm"></a><p>
    Unique constraints ensure that the data contained in a column, or a
    group of columns, is unique among all the rows in the
    table.  The syntax is:
</p><pre class="programlisting">
CREATE TABLE products (
    product_no integer <span class="emphasis"><strong>UNIQUE</strong></span>,
    name text,
    price numeric
);
</pre><p>
    when written as a column constraint, and:
</p><pre class="programlisting">
CREATE TABLE products (
    product_no integer,
    name text,
    price numeric,
    <span class="emphasis"><strong>UNIQUE (product_no)</strong></span>
);
</pre><p>
    when written as a table constraint.
   </p><p>
    To define a unique constraint for a group of columns, write it as a
    table constraint with the column names separated by commas:
</p><pre class="programlisting">
CREATE TABLE example (
    a integer,
    b integer,
    c integer,
    <span class="emphasis"><strong>UNIQUE (a, c)</strong></span>
);
</pre><p>
    This specifies that the combination of values in the indicated columns
    is unique across the whole table, though any one of the columns
    need not be (and ordinarily isn't) unique.
   </p><p>
    You can assign your own name for a unique constraint, in the usual way:
</p><pre class="programlisting">
CREATE TABLE products (
    product_no integer <span class="emphasis"><strong>CONSTRAINT must_be_different</strong></span> UNIQUE,
    name text,
    price numeric
);
</pre><p>
   </p><p>
    Adding a unique constraint will automatically create a unique B-tree
    index on the column or group of columns listed in the constraint.
    A uniqueness restriction covering only some rows cannot be written as
    a unique constraint, but it is possible to enforce such a restriction by
    creating a unique <a class="link" href="indexes-partial.html" title="11.8. Partial Indexes">partial index</a>.
   </p><a id="id-1.5.4.6.7.8" class="indexterm"></a><p>
    In general, a unique constraint is violated if there is more than
    one row in the table where the values of all of the
    columns included in the constraint are equal.
    By default, two null values are not considered equal in this
    comparison.  That means even in the presence of a
    unique constraint it is possible to store duplicate
    rows that contain a null value in at least one of the constrained
    columns.  This behavior can be changed by adding the clause <code class="literal">NULLS
    NOT DISTINCT</code>, like
</p><pre class="programlisting">
CREATE TABLE products (
    product_no integer UNIQUE <span class="emphasis"><strong>NULLS NOT DISTINCT</strong></span>,
    name text,
    price numeric
);
</pre><p>
    or
</p><pre class="programlisting">
CREATE TABLE products (
    product_no integer,
    name text,
    price numeric,
    UNIQUE <span class="emphasis"><strong>NULLS NOT DISTINCT</strong></span> (product_no)
);
</pre><p>
    The default behavior can be specified explicitly using <code class="literal">NULLS
    DISTINCT</code>.  The default null treatment in unique constraints is
    implementation-defined according to the SQL standard, and other
    implementations have a different behavior.  So be careful when developing
    applications that are intended to be portable.
   </p></div><div class="sect2" id="DDL-CONSTRAINTS-PRIMARY-KEYS"><div class="titlepage"><div><div><h3 class="title">5.4.4. Primary Keys</h3></div></div></div><a id="id-1.5.4.6.8.2" class="indexterm"></a><a id="id-1.5.4.6.8.3" class="indexterm"></a><p>
    A primary key constraint indicates that a column, or group of columns,
    can be used as a unique identifier for rows in the table.  This
    requires that the values be both unique and not null.  So, the following
    two table definitions accept the same data:
</p><pre class="programlisting">
CREATE TABLE products (
    product_no integer UNIQUE NOT NULL,
    name text,
    price numeric
);
</pre><p>

</p><pre class="programlisting">
CREATE TABLE products (
    product_no integer <span class="emphasis"><strong>PRIMARY KEY</strong></span>,
    name text,
    price numeric
);
</pre><p>
   </p><p>
    Primary keys can span more than one column; the syntax
    is similar to unique constraints:
</p><pre class="programlisting">
CREATE TABLE example (
    a integer,
    b integer,
    c integer,
    <span class="emphasis"><strong>PRIMARY KEY (a, c)</strong></span>
);
</pre><p>
   </p><p>
    Adding a primary key will automatically create a unique B-tree index
    on the column or group of columns listed in the primary key, and will
    force the column(s) to be marked <code class="literal">NOT NULL</code>.
   </p><p>
    A table can have at most one primary key.  (There can be any number
    of unique and not-null constraints, which are functionally almost the
    same thing, but only one can be identified as the primary key.)
    Relational database theory
    dictates that every table must have a primary key.  This rule is
    not enforced by <span class="productname">PostgreSQL</span>, but it is
    usually best to follow it.
   </p><p>
    Primary keys are useful both for
    documentation purposes and for client applications.  For example,
    a GUI application that allows modifying row values probably needs
    to know the primary key of a table to be able to identify rows
    uniquely.  There are also various ways in which the database system
    makes use of a primary key if one has been declared; for example,
    the primary key defines the default target column(s) for foreign keys
    referencing its table.
   </p></div><div class="sect2" id="DDL-CONSTRAINTS-FK"><div class="titlepage"><div><div><h3 class="title">5.4.5. Foreign Keys</h3></div></div></div><a id="id-1.5.4.6.9.2" class="indexterm"></a><a id="id-1.5.4.6.9.3" class="indexterm"></a><a id="id-1.5.4.6.9.4" class="indexterm"></a><p>
    A foreign key constraint specifies that the values in a column (or
    a group of columns) must match the values appearing in some row
    of another table.
    We say this maintains the <em class="firstterm">referential
    integrity</em> between two related tables.
   </p><p>
    Say you have the product table that we have used several times already:
</p><pre class="programlisting">
CREATE TABLE products (
    product_no integer PRIMARY KEY,
    name text,
    price numeric
);
</pre><p>
    Let's also assume you have a table storing orders of those
    products.  We want to ensure that the orders table only contains
    orders of products that actually exist.  So we define a foreign
    key constraint in the orders table that references the products
    table:
</p><pre class="programlisting">
CREATE TABLE orders (
    order_id integer PRIMARY KEY,
    product_no integer <span class="emphasis"><strong>REFERENCES products (product_no)</strong></span>,
    quantity integer
);
</pre><p>
    Now it is impossible to create orders with non-NULL
    <code class="structfield">product_no</code> entries that do not appear in the
    products table.
   </p><p>
    We say that in this situation the orders table is the
    <em class="firstterm">referencing</em> table and the products table is
    the <em class="firstterm">referenced</em> table.  Similarly, there are
    referencing and referenced columns.
   </p><p>
    You can also shorten the above command to:
</p><pre class="programlisting">
CREATE TABLE orders (
    order_id integer PRIMARY KEY,
    product_no integer <span class="emphasis"><strong>REFERENCES products</strong></span>,
    quantity integer
);
</pre><p>
    because in absence of a column list the primary key of the
    referenced table is used as the referenced column(s).
   </p><p>
    You can assign your own name for a foreign key constraint,
    in the usual way.
   </p><p>
    A foreign key can also constrain and reference a group of columns.
    As usual, it then needs to be written in table constraint form.
    Here is a contrived syntax example:
</p><pre class="programlisting">
CREATE TABLE t1 (
  a integer PRIMARY KEY,
  b integer,
  c integer,
  <span class="emphasis"><strong>FOREIGN KEY (b, c) REFERENCES other_table (c1, c2)</strong></span>
);
</pre><p>
    Of course, the number and type of the constrained columns need to
    match the number and type of the referenced columns.
   </p><a id="id-1.5.4.6.9.11" class="indexterm"></a><p>
    Sometimes it is useful for the <span class="quote">“<span class="quote">other table</span>”</span> of a
    foreign key constraint to be the same table; this is called
    a <em class="firstterm">self-referential</em> foreign key.  For
    example, if you want rows of a table to represent nodes of a tree
    structure, you could write
</p><pre class="programlisting">
CREATE TABLE tree (
    node_id integer PRIMARY KEY,
    parent_id integer REFERENCES tree,
    name text,
    ...
);
</pre><p>
    A top-level node would have NULL <code class="structfield">parent_id</code>,
    while non-NULL <code class="structfield">parent_id</code> entries would be
    constrained to reference valid rows of the table.
   </p><p>
    A table can have more than one foreign key constraint.  This is
    used to implement many-to-many relationships between tables.  Say
    you have tables about products and orders, but now you want to
    allow one order to contain possibly many products (which the
    structure above did not allow).  You could use this table structure:
</p><pre class="programlisting">
CREATE TABLE products (
    product_no integer PRIMARY KEY,
    name text,
    price numeric
);

CREATE TABLE orders (
    order_id integer PRIMARY KEY,
    shipping_address text,
    ...
);

CREATE TABLE order_items (
    product_no integer REFERENCES products,
    order_id integer REFERENCES orders,
    quantity integer,
    PRIMARY KEY (product_no, order_id)
);
</pre><p>
    Notice that the primary key overlaps with the foreign keys in
    the last table.
   </p><a id="id-1.5.4.6.9.14" class="indexterm"></a><a id="id-1.5.4.6.9.15" class="indexterm"></a><p>
    We know that the foreign keys disallow creation of orders that
    do not relate to any products.  But what if a product is removed
    after an order is created that references it?  SQL allows you to
    handle that as well.  Intuitively, we have a few options:
    </p><div class="itemizedlist"><ul class="itemizedlist compact" style="list-style-type: disc; "><li class="listitem"><p>Disallow deleting a referenced product</p></li><li class="listitem"><p>Delete the orders as well</p></li><li class="listitem"><p>Something else?</p></li></ul></div><p>
   </p><p>
    To illustrate this, let's implement the following policy on the
    many-to-many relationship example above: when someone wants to
    remove a product that is still referenced by an order (via
    <code class="literal">order_items</code>), we disallow it.  If someone
    removes an order, the order items are removed as well:
</p><pre class="programlisting">
CREATE TABLE products (
    product_no integer PRIMARY KEY,
    name text,
    price numeric
);

CREATE TABLE orders (
    order_id integer PRIMARY KEY,
    shipping_address text,
    ...
);

CREATE TABLE order_items (
    product_no integer REFERENCES products <span class="emphasis"><strong>ON DELETE RESTRICT</strong></span>,
    order_id integer REFERENCES orders <span class="emphasis"><strong>ON DELETE CASCADE</strong></span>,
    quantity integer,
    PRIMARY KEY (product_no, order_id)
);
</pre><p>
   </p><p>
    Restricting and cascading deletes are the two most common options.
    <code class="literal">RESTRICT</code> prevents deletion of a
    referenced row. <code class="literal">NO ACTION</code> means that if any
    referencing rows still exist when the constraint is checked, an error
    is raised; this is the default behavior if you do not specify anything.
    (The essential difference between these two choices is that
    <code class="literal">NO ACTION</code> allows the check to be deferred until
    later in the transaction, whereas <code class="literal">RESTRICT</code> does not.)
    <code class="literal">CASCADE</code> specifies that when a referenced row is deleted,
    row(s) referencing it should be automatically deleted as well.
    There are two other options:
    <code class="literal">SET NULL</code> and <code class="literal">SET DEFAULT</code>.
    These cause the referencing column(s) in the referencing row(s)
    to be set to nulls or their default
    values, respectively, when the referenced row is deleted.
    Note that these do not excuse you from observing any constraints.
    For example, if an action specifies <code class="literal">SET DEFAULT</code>
    but the default value would not satisfy the foreign key constraint, the
    operation will fail.
   </p><p>
    The appropriate choice of <code class="literal">ON DELETE</code> action depends on
    what kinds of objects the related tables represent.  When the referencing
    table represents something that is a component of what is represented by
    the referenced table and cannot exist independently, then
    <code class="literal">CASCADE</code> could be appropriate.  If the two tables
    represent independent objects, then <code class="literal">RESTRICT</code> or
    <code class="literal">NO ACTION</code> is more appropriate; an application that
    actually wants to delete both objects would then have to be explicit about
    this and run two delete commands.  In the above example, order items are
    part of an order, and it is convenient if they are deleted automatically
    if an order is deleted.  But products and orders are different things, and
    so making a deletion of a product automatically cause the deletion of some
    order items could be considered problematic.  The actions <code class="literal">SET
    NULL</code> or <code class="literal">SET DEFAULT</code> can be appropriate if a
    foreign-key relationship represents optional information.  For example, if
    the products table contained a reference to a product manager, and the
    product manager entry gets deleted, then setting the product's product
    manager to null or a default might be useful.
   </p><p>
    The actions <code class="literal">SET NULL</code> and <code class="literal">SET DEFAULT</code>
    can take a column list to specify which columns to set.  Normally, all
    columns of the foreign-key constraint are set; setting only a subset is
    useful in some special cases.  Consider the following example:
</p><pre class="programlisting">
CREATE TABLE tenants (
    tenant_id integer PRIMARY KEY
);

CREATE TABLE users (
    tenant_id integer REFERENCES tenants ON DELETE CASCADE,
    user_id integer NOT NULL,
    PRIMARY KEY (tenant_id, user_id)
);

CREATE TABLE posts (
    tenant_id integer REFERENCES tenants ON DELETE CASCADE,
    post_id integer NOT NULL,
    author_id integer,
    PRIMARY KEY (tenant_id, post_id),
    FOREIGN KEY (tenant_id, author_id) REFERENCES users ON DELETE SET NULL <span class="emphasis"><strong>(author_id)</strong></span>
);
</pre><p>
    Without the specification of the column, the foreign key would also set
    the column <code class="literal">tenant_id</code> to null, but that column is still
    required as part of the primary key.
   </p><p>
    Analogous to <code class="literal">ON DELETE</code> there is also
    <code class="literal">ON UPDATE</code> which is invoked when a referenced
    column is changed (updated).  The possible actions are the same,
    except that column lists cannot be specified for <code class="literal">SET
    NULL</code> and <code class="literal">SET DEFAULT</code>.
    In this case, <code class="literal">CASCADE</code> means that the updated values of the
    referenced column(s) should be copied into the referencing row(s).
   </p><p>
    Normally, a referencing row need not satisfy the foreign key constraint
    if any of its referencing columns are null.  If <code class="literal">MATCH FULL</code>
    is added to the foreign key declaration, a referencing row escapes
    satisfying the constraint only if all its referencing columns are null
    (so a mix of null and non-null values is guaranteed to fail a
    <code class="literal">MATCH FULL</code> constraint).  If you don't want referencing rows
    to be able to avoid satisfying the foreign key constraint, declare the
    referencing column(s) as <code class="literal">NOT NULL</code>.
   </p><p>
    A foreign key must reference columns that either are a primary key or
    form a unique constraint, or are columns from a non-partial unique index.
    This means that the referenced columns always have an index to allow
    efficient lookups on whether a referencing row has a match.  Since a
    <code class="command">DELETE</code> of a row from the referenced table or an
    <code class="command">UPDATE</code> of a referenced column will require a scan of
    the referencing table for rows matching the old value, it is often a good
    idea to index the referencing columns too.  Because this is not always
    needed, and there are many choices available on how to index, the
    declaration of a foreign key constraint does not automatically create an
    index on the referencing columns.
   </p><p>
    More information about updating and deleting data is in <a class="xref" href="dml.html" title="Chapter 6. Data Manipulation">Chapter 6</a>.  Also see the description of foreign key constraint
    syntax in the reference documentation for
    <a class="xref" href="sql-createtable.html" title="CREATE TABLE"><span class="refentrytitle">CREATE TABLE</span></a>.
   </p></div><div class="sect2" id="DDL-CONSTRAINTS-EXCLUSION"><div class="titlepage"><div><div><h3 class="title">5.4.6. Exclusion Constraints</h3></div></div></div><a id="id-1.5.4.6.10.2" class="indexterm"></a><a id="id-1.5.4.6.10.3" class="indexterm"></a><p>
    Exclusion constraints ensure that if any two rows are compared on
    the specified columns or expressions using the specified operators,
    at least one of these operator comparisons will return false or null.
    The syntax is:
</p><pre class="programlisting">
CREATE TABLE circles (
    c circle,
    EXCLUDE USING gist (c WITH &amp;&amp;)
);
</pre><p>
   </p><p>
    See also <a class="link" href="sql-createtable.html#SQL-CREATETABLE-EXCLUDE"><code class="command">CREATE
    TABLE ... CONSTRAINT ... EXCLUDE</code></a> for details.
   </p><p>
    Adding an exclusion constraint will automatically create an index
    of the type specified in the constraint declaration.
   </p></div></div><div class="navfooter"><hr /><table width="100%" summary="Navigation footer"><tr><td width="40%" align="left"><a accesskey="p" href="ddl-generated-columns.html" title="5.3. Generated Columns">Prev</a> </td><td width="20%" align="center"><a accesskey="u" href="ddl.html" title="Chapter 5. Data Definition">Up</a></td><td width="40%" align="right"> <a accesskey="n" href="ddl-system-columns.html" title="5.5. System Columns">Next</a></td></tr><tr><td width="40%" align="left" valign="top">5.3. Generated Columns </td><td width="20%" align="center"><a accesskey="h" href="index.html" title="PostgreSQL 15.6 Documentation">Home</a></td><td width="40%" align="right" valign="top"> 5.5. System Columns</td></tr></table></div></body></html>