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+<!-- doc/src/sgml/xoper.sgml -->
+
+ <sect1 id="xoper">
+ <title>User-Defined Operators</title>
+
+ <indexterm zone="xoper">
+ <primary>operator</primary>
+ <secondary>user-defined</secondary>
+ </indexterm>
+
+ <para>
+ Every operator is <quote>syntactic sugar</quote> for a call to an
+ underlying function that does the real work; so you must
+ first create the underlying function before you can create
+ the operator. However, an operator is <emphasis>not merely</emphasis>
+ syntactic sugar, because it carries additional information
+ that helps the query planner optimize queries that use the
+ operator. The next section will be devoted to explaining
+ that additional information.
+ </para>
+
+ <para>
+ <productname>PostgreSQL</productname> supports prefix
+ and infix operators. Operators can be
+ overloaded;<indexterm><primary>overloading</primary><secondary>operators</secondary></indexterm>
+ that is, the same operator name can be used for different operators
+ that have different numbers and types of operands. When a query is
+ executed, the system determines the operator to call from the
+ number and types of the provided operands.
+ </para>
+
+ <para>
+ Here is an example of creating an operator for adding two complex
+ numbers. We assume we've already created the definition of type
+ <type>complex</type> (see <xref linkend="xtypes"/>). First we need a
+ function that does the work, then we can define the operator:
+
+<programlisting>
+CREATE FUNCTION complex_add(complex, complex)
+ RETURNS complex
+ AS '<replaceable>filename</replaceable>', 'complex_add'
+ LANGUAGE C IMMUTABLE STRICT;
+
+CREATE OPERATOR + (
+ leftarg = complex,
+ rightarg = complex,
+ function = complex_add,
+ commutator = +
+);
+</programlisting>
+ </para>
+
+ <para>
+ Now we could execute a query like this:
+
+<screen>
+SELECT (a + b) AS c FROM test_complex;
+
+ c
+-----------------
+ (5.2,6.05)
+ (133.42,144.95)
+</screen>
+ </para>
+
+ <para>
+ We've shown how to create a binary operator here. To create a prefix
+ operator, just omit the <literal>leftarg</literal>.
+ The <literal>function</literal>
+ clause and the argument clauses are the only required items in
+ <command>CREATE OPERATOR</command>. The <literal>commutator</literal>
+ clause shown in the example is an optional hint to the query
+ optimizer. Further details about <literal>commutator</literal> and other
+ optimizer hints appear in the next section.
+ </para>
+ </sect1>
+
+ <sect1 id="xoper-optimization">
+ <title>Operator Optimization Information</title>
+
+ <indexterm zone="xoper-optimization">
+ <primary>optimization information</primary>
+ <secondary>for operators</secondary>
+ </indexterm>
+
+ <para>
+ A <productname>PostgreSQL</productname> operator definition can include
+ several optional clauses that tell the system useful things about how
+ the operator behaves. These clauses should be provided whenever
+ appropriate, because they can make for considerable speedups in execution
+ of queries that use the operator. But if you provide them, you must be
+ sure that they are right! Incorrect use of an optimization clause can
+ result in slow queries, subtly wrong output, or other Bad Things.
+ You can always leave out an optimization clause if you are not sure
+ about it; the only consequence is that queries might run slower than
+ they need to.
+ </para>
+
+ <para>
+ Additional optimization clauses might be added in future versions of
+ <productname>PostgreSQL</productname>. The ones described here are all
+ the ones that release &version; understands.
+ </para>
+
+ <para>
+ It is also possible to attach a planner support function to the function
+ that underlies an operator, providing another way of telling the system
+ about the behavior of the operator.
+ See <xref linkend="xfunc-optimization"/> for more information.
+ </para>
+
+ <sect2>
+ <title><literal>COMMUTATOR</literal></title>
+
+ <para>
+ The <literal>COMMUTATOR</literal> clause, if provided, names an operator that is the
+ commutator of the operator being defined. We say that operator A is the
+ commutator of operator B if (x A y) equals (y B x) for all possible input
+ values x, y. Notice that B is also the commutator of A. For example,
+ operators <literal>&lt;</literal> and <literal>&gt;</literal> for a particular data type are usually each others'
+ commutators, and operator <literal>+</literal> is usually commutative with itself.
+ But operator <literal>-</literal> is usually not commutative with anything.
+ </para>
+
+ <para>
+ The left operand type of a commutable operator is the same as the
+ right operand type of its commutator, and vice versa. So the name of
+ the commutator operator is all that <productname>PostgreSQL</productname>
+ needs to be given to look up the commutator, and that's all that needs to
+ be provided in the <literal>COMMUTATOR</literal> clause.
+ </para>
+
+ <para>
+ It's critical to provide commutator information for operators that
+ will be used in indexes and join clauses, because this allows the
+ query optimizer to <quote>flip around</quote> such a clause to the forms
+ needed for different plan types. For example, consider a query with
+ a WHERE clause like <literal>tab1.x = tab2.y</literal>, where <literal>tab1.x</literal>
+ and <literal>tab2.y</literal> are of a user-defined type, and suppose that
+ <literal>tab2.y</literal> is indexed. The optimizer cannot generate an
+ index scan unless it can determine how to flip the clause around to
+ <literal>tab2.y = tab1.x</literal>, because the index-scan machinery expects
+ to see the indexed column on the left of the operator it is given.
+ <productname>PostgreSQL</productname> will <emphasis>not</emphasis> simply
+ assume that this is a valid transformation &mdash; the creator of the
+ <literal>=</literal> operator must specify that it is valid, by marking the
+ operator with commutator information.
+ </para>
+
+ <para>
+ When you are defining a self-commutative operator, you just do it.
+ When you are defining a pair of commutative operators, things are
+ a little trickier: how can the first one to be defined refer to the
+ other one, which you haven't defined yet? There are two solutions
+ to this problem:
+
+ <itemizedlist>
+ <listitem>
+ <para>
+ One way is to omit the <literal>COMMUTATOR</literal> clause in the first operator that
+ you define, and then provide one in the second operator's definition.
+ Since <productname>PostgreSQL</productname> knows that commutative
+ operators come in pairs, when it sees the second definition it will
+ automatically go back and fill in the missing <literal>COMMUTATOR</literal> clause in
+ the first definition.
+ </para>
+ </listitem>
+
+ <listitem>
+ <para>
+ The other, more straightforward way is just to include <literal>COMMUTATOR</literal> clauses
+ in both definitions. When <productname>PostgreSQL</productname> processes
+ the first definition and realizes that <literal>COMMUTATOR</literal> refers to a nonexistent
+ operator, the system will make a dummy entry for that operator in the
+ system catalog. This dummy entry will have valid data only
+ for the operator name, left and right operand types, and result type,
+ since that's all that <productname>PostgreSQL</productname> can deduce
+ at this point. The first operator's catalog entry will link to this
+ dummy entry. Later, when you define the second operator, the system
+ updates the dummy entry with the additional information from the second
+ definition. If you try to use the dummy operator before it's been filled
+ in, you'll just get an error message.
+ </para>
+ </listitem>
+ </itemizedlist>
+ </para>
+ </sect2>
+
+ <sect2>
+ <title><literal>NEGATOR</literal></title>
+
+ <para>
+ The <literal>NEGATOR</literal> clause, if provided, names an operator that is the
+ negator of the operator being defined. We say that operator A
+ is the negator of operator B if both return Boolean results and
+ (x A y) equals NOT (x B y) for all possible inputs x, y.
+ Notice that B is also the negator of A.
+ For example, <literal>&lt;</literal> and <literal>&gt;=</literal> are a negator pair for most data types.
+ An operator can never validly be its own negator.
+ </para>
+
+ <para>
+ Unlike commutators, a pair of unary operators could validly be marked
+ as each other's negators; that would mean (A x) equals NOT (B x)
+ for all x.
+ </para>
+
+ <para>
+ An operator's negator must have the same left and/or right operand types
+ as the operator to be defined, so just as with <literal>COMMUTATOR</literal>, only the operator
+ name need be given in the <literal>NEGATOR</literal> clause.
+ </para>
+
+ <para>
+ Providing a negator is very helpful to the query optimizer since
+ it allows expressions like <literal>NOT (x = y)</literal> to be simplified into
+ <literal>x &lt;&gt; y</literal>. This comes up more often than you might think, because
+ <literal>NOT</literal> operations can be inserted as a consequence of other rearrangements.
+ </para>
+
+ <para>
+ Pairs of negator operators can be defined using the same methods
+ explained above for commutator pairs.
+ </para>
+
+ </sect2>
+
+ <sect2>
+ <title><literal>RESTRICT</literal></title>
+
+ <para>
+ The <literal>RESTRICT</literal> clause, if provided, names a restriction selectivity
+ estimation function for the operator. (Note that this is a function
+ name, not an operator name.) <literal>RESTRICT</literal> clauses only make sense for
+ binary operators that return <type>boolean</type>. The idea behind a restriction
+ selectivity estimator is to guess what fraction of the rows in a
+ table will satisfy a <literal>WHERE</literal>-clause condition of the form:
+<programlisting>
+column OP constant
+</programlisting>
+ for the current operator and a particular constant value.
+ This assists the optimizer by
+ giving it some idea of how many rows will be eliminated by <literal>WHERE</literal>
+ clauses that have this form. (What happens if the constant is on
+ the left, you might be wondering? Well, that's one of the things that
+ <literal>COMMUTATOR</literal> is for...)
+ </para>
+
+ <para>
+ Writing new restriction selectivity estimation functions is far beyond
+ the scope of this chapter, but fortunately you can usually just use
+ one of the system's standard estimators for many of your own operators.
+ These are the standard restriction estimators:
+ <simplelist>
+ <member><function>eqsel</function> for <literal>=</literal></member>
+ <member><function>neqsel</function> for <literal>&lt;&gt;</literal></member>
+ <member><function>scalarltsel</function> for <literal>&lt;</literal></member>
+ <member><function>scalarlesel</function> for <literal>&lt;=</literal></member>
+ <member><function>scalargtsel</function> for <literal>&gt;</literal></member>
+ <member><function>scalargesel</function> for <literal>&gt;=</literal></member>
+ </simplelist>
+ </para>
+
+ <para>
+ You can frequently get away with using either <function>eqsel</function> or <function>neqsel</function> for
+ operators that have very high or very low selectivity, even if they
+ aren't really equality or inequality. For example, the
+ approximate-equality geometric operators use <function>eqsel</function> on the assumption that
+ they'll usually only match a small fraction of the entries in a table.
+ </para>
+
+ <para>
+ You can use <function>scalarltsel</function>, <function>scalarlesel</function>,
+ <function>scalargtsel</function> and <function>scalargesel</function> for comparisons on
+ data types that have some sensible means of being converted into numeric
+ scalars for range comparisons. If possible, add the data type to those
+ understood by the function <function>convert_to_scalar()</function> in
+ <filename>src/backend/utils/adt/selfuncs.c</filename>.
+ (Eventually, this function should be replaced by per-data-type functions
+ identified through a column of the <classname>pg_type</classname> system catalog; but that hasn't happened
+ yet.) If you do not do this, things will still work, but the optimizer's
+ estimates won't be as good as they could be.
+ </para>
+
+ <para>
+ Another useful built-in selectivity estimation function
+ is <function>matchingsel</function>, which will work for almost any
+ binary operator, if standard MCV and/or histogram statistics are
+ collected for the input data type(s). Its default estimate is set to
+ twice the default estimate used in <function>eqsel</function>, making
+ it most suitable for comparison operators that are somewhat less
+ strict than equality. (Or you could call the
+ underlying <function>generic_restriction_selectivity</function>
+ function, providing a different default estimate.)
+ </para>
+
+ <para>
+ There are additional selectivity estimation functions designed for geometric
+ operators in <filename>src/backend/utils/adt/geo_selfuncs.c</filename>: <function>areasel</function>, <function>positionsel</function>,
+ and <function>contsel</function>. At this writing these are just stubs, but you might want
+ to use them (or even better, improve them) anyway.
+ </para>
+ </sect2>
+
+ <sect2>
+ <title><literal>JOIN</literal></title>
+
+ <para>
+ The <literal>JOIN</literal> clause, if provided, names a join selectivity
+ estimation function for the operator. (Note that this is a function
+ name, not an operator name.) <literal>JOIN</literal> clauses only make sense for
+ binary operators that return <type>boolean</type>. The idea behind a join
+ selectivity estimator is to guess what fraction of the rows in a
+ pair of tables will satisfy a <literal>WHERE</literal>-clause condition of the form:
+<programlisting>
+table1.column1 OP table2.column2
+</programlisting>
+ for the current operator. As with the <literal>RESTRICT</literal> clause, this helps
+ the optimizer very substantially by letting it figure out which
+ of several possible join sequences is likely to take the least work.
+ </para>
+
+ <para>
+ As before, this chapter will make no attempt to explain how to write
+ a join selectivity estimator function, but will just suggest that
+ you use one of the standard estimators if one is applicable:
+ <simplelist>
+ <member><function>eqjoinsel</function> for <literal>=</literal></member>
+ <member><function>neqjoinsel</function> for <literal>&lt;&gt;</literal></member>
+ <member><function>scalarltjoinsel</function> for <literal>&lt;</literal></member>
+ <member><function>scalarlejoinsel</function> for <literal>&lt;=</literal></member>
+ <member><function>scalargtjoinsel</function> for <literal>&gt;</literal></member>
+ <member><function>scalargejoinsel</function> for <literal>&gt;=</literal></member>
+ <member><function>matchingjoinsel</function> for generic matching operators</member>
+ <member><function>areajoinsel</function> for 2D area-based comparisons</member>
+ <member><function>positionjoinsel</function> for 2D position-based comparisons</member>
+ <member><function>contjoinsel</function> for 2D containment-based comparisons</member>
+ </simplelist>
+ </para>
+ </sect2>
+
+ <sect2>
+ <title><literal>HASHES</literal></title>
+
+ <para>
+ The <literal>HASHES</literal> clause, if present, tells the system that
+ it is permissible to use the hash join method for a join based on this
+ operator. <literal>HASHES</literal> only makes sense for a binary operator that
+ returns <literal>boolean</literal>, and in practice the operator must represent
+ equality for some data type or pair of data types.
+ </para>
+
+ <para>
+ The assumption underlying hash join is that the join operator can
+ only return true for pairs of left and right values that hash to the
+ same hash code. If two values get put in different hash buckets, the
+ join will never compare them at all, implicitly assuming that the
+ result of the join operator must be false. So it never makes sense
+ to specify <literal>HASHES</literal> for operators that do not represent
+ some form of equality. In most cases it is only practical to support
+ hashing for operators that take the same data type on both sides.
+ However, sometimes it is possible to design compatible hash functions
+ for two or more data types; that is, functions that will generate the
+ same hash codes for <quote>equal</quote> values, even though the values
+ have different representations. For example, it's fairly simple
+ to arrange this property when hashing integers of different widths.
+ </para>
+
+ <para>
+ To be marked <literal>HASHES</literal>, the join operator must appear
+ in a hash index operator family. This is not enforced when you create
+ the operator, since of course the referencing operator family couldn't
+ exist yet. But attempts to use the operator in hash joins will fail
+ at run time if no such operator family exists. The system needs the
+ operator family to find the data-type-specific hash function(s) for the
+ operator's input data type(s). Of course, you must also create suitable
+ hash functions before you can create the operator family.
+ </para>
+
+ <para>
+ Care should be exercised when preparing a hash function, because there
+ are machine-dependent ways in which it might fail to do the right thing.
+ For example, if your data type is a structure in which there might be
+ uninteresting pad bits, you cannot simply pass the whole structure to
+ <function>hash_any</function>. (Unless you write your other operators and
+ functions to ensure that the unused bits are always zero, which is the
+ recommended strategy.)
+ Another example is that on machines that meet the <acronym>IEEE</acronym>
+ floating-point standard, negative zero and positive zero are different
+ values (different bit patterns) but they are defined to compare equal.
+ If a float value might contain negative zero then extra steps are needed
+ to ensure it generates the same hash value as positive zero.
+ </para>
+
+ <para>
+ A hash-joinable operator must have a commutator (itself if the two
+ operand data types are the same, or a related equality operator
+ if they are different) that appears in the same operator family.
+ If this is not the case, planner errors might occur when the operator
+ is used. Also, it is a good idea (but not strictly required) for
+ a hash operator family that supports multiple data types to provide
+ equality operators for every combination of the data types; this
+ allows better optimization.
+ </para>
+
+ <note>
+ <para>
+ The function underlying a hash-joinable operator must be marked
+ immutable or stable. If it is volatile, the system will never
+ attempt to use the operator for a hash join.
+ </para>
+ </note>
+
+ <note>
+ <para>
+ If a hash-joinable operator has an underlying function that is marked
+ strict, the
+ function must also be complete: that is, it should return true or
+ false, never null, for any two nonnull inputs. If this rule is
+ not followed, hash-optimization of <literal>IN</literal> operations might
+ generate wrong results. (Specifically, <literal>IN</literal> might return
+ false where the correct answer according to the standard would be null;
+ or it might yield an error complaining that it wasn't prepared for a
+ null result.)
+ </para>
+ </note>
+
+ </sect2>
+
+ <sect2>
+ <title><literal>MERGES</literal></title>
+
+ <para>
+ The <literal>MERGES</literal> clause, if present, tells the system that
+ it is permissible to use the merge-join method for a join based on this
+ operator. <literal>MERGES</literal> only makes sense for a binary operator that
+ returns <literal>boolean</literal>, and in practice the operator must represent
+ equality for some data type or pair of data types.
+ </para>
+
+ <para>
+ Merge join is based on the idea of sorting the left- and right-hand tables
+ into order and then scanning them in parallel. So, both data types must
+ be capable of being fully ordered, and the join operator must be one
+ that can only succeed for pairs of values that fall at the
+ <quote>same place</quote>
+ in the sort order. In practice this means that the join operator must
+ behave like equality. But it is possible to merge-join two
+ distinct data types so long as they are logically compatible. For
+ example, the <type>smallint</type>-versus-<type>integer</type>
+ equality operator is merge-joinable.
+ We only need sorting operators that will bring both data types into a
+ logically compatible sequence.
+ </para>
+
+ <para>
+ To be marked <literal>MERGES</literal>, the join operator must appear
+ as an equality member of a <literal>btree</literal> index operator family.
+ This is not enforced when you create
+ the operator, since of course the referencing operator family couldn't
+ exist yet. But the operator will not actually be used for merge joins
+ unless a matching operator family can be found. The
+ <literal>MERGES</literal> flag thus acts as a hint to the planner that
+ it's worth looking for a matching operator family.
+ </para>
+
+ <para>
+ A merge-joinable operator must have a commutator (itself if the two
+ operand data types are the same, or a related equality operator
+ if they are different) that appears in the same operator family.
+ If this is not the case, planner errors might occur when the operator
+ is used. Also, it is a good idea (but not strictly required) for
+ a <literal>btree</literal> operator family that supports multiple data types to provide
+ equality operators for every combination of the data types; this
+ allows better optimization.
+ </para>
+
+ <note>
+ <para>
+ The function underlying a merge-joinable operator must be marked
+ immutable or stable. If it is volatile, the system will never
+ attempt to use the operator for a merge join.
+ </para>
+ </note>
+ </sect2>
+ </sect1>