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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>14.3. Controlling the Planner with Explicit JOIN Clauses</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="planner-stats.html" title="14.2. Statistics Used by the Planner" /><link rel="next" href="populate.html" title="14.4. Populating a Database" /></head><body id="docContent" class="container-fluid col-10"><div class="navheader"><table width="100%" summary="Navigation header"><tr><th colspan="5" align="center">14.3. Controlling the Planner with Explicit <code class="literal">JOIN</code> Clauses</th></tr><tr><td width="10%" align="left"><a accesskey="p" href="planner-stats.html" title="14.2. Statistics Used by the Planner">Prev</a> </td><td width="10%" align="left"><a accesskey="u" href="performance-tips.html" title="Chapter 14. Performance Tips">Up</a></td><th width="60%" align="center">Chapter 14. Performance Tips</th><td width="10%" align="right"><a accesskey="h" href="index.html" title="PostgreSQL 16.3 Documentation">Home</a></td><td width="10%" align="right"> <a accesskey="n" href="populate.html" title="14.4. Populating a Database">Next</a></td></tr></table><hr /></div><div class="sect1" id="EXPLICIT-JOINS"><div class="titlepage"><div><div><h2 class="title" style="clear: both">14.3. Controlling the Planner with Explicit <code class="literal">JOIN</code> Clauses <a href="#EXPLICIT-JOINS" class="id_link">#</a></h2></div></div></div><a id="id-1.5.13.6.2" class="indexterm"></a><p>
It is possible
to control the query planner to some extent by using the explicit <code class="literal">JOIN</code>
syntax. To see why this matters, we first need some background.
</p><p>
In a simple join query, such as:
</p><pre class="programlisting">
SELECT * FROM a, b, c WHERE a.id = b.id AND b.ref = c.id;
</pre><p>
the planner is free to join the given tables in any order. For
example, it could generate a query plan that joins A to B, using
the <code class="literal">WHERE</code> condition <code class="literal">a.id = b.id</code>, and then
joins C to this joined table, using the other <code class="literal">WHERE</code>
condition. Or it could join B to C and then join A to that result.
Or it could join A to C and then join them with B — but that
would be inefficient, since the full Cartesian product of A and C
would have to be formed, there being no applicable condition in the
<code class="literal">WHERE</code> clause to allow optimization of the join. (All
joins in the <span class="productname">PostgreSQL</span> executor happen
between two input tables, so it's necessary to build up the result
in one or another of these fashions.) The important point is that
these different join possibilities give semantically equivalent
results but might have hugely different execution costs. Therefore,
the planner will explore all of them to try to find the most
efficient query plan.
</p><p>
When a query only involves two or three tables, there aren't many join
orders to worry about. But the number of possible join orders grows
exponentially as the number of tables expands. Beyond ten or so input
tables it's no longer practical to do an exhaustive search of all the
possibilities, and even for six or seven tables planning might take an
annoyingly long time. When there are too many input tables, the
<span class="productname">PostgreSQL</span> planner will switch from exhaustive
search to a <em class="firstterm">genetic</em> probabilistic search
through a limited number of possibilities. (The switch-over threshold is
set by the <a class="xref" href="runtime-config-query.html#GUC-GEQO-THRESHOLD">geqo_threshold</a> run-time
parameter.)
The genetic search takes less time, but it won't
necessarily find the best possible plan.
</p><p>
When the query involves outer joins, the planner has less freedom
than it does for plain (inner) joins. For example, consider:
</p><pre class="programlisting">
SELECT * FROM a LEFT JOIN (b JOIN c ON (b.ref = c.id)) ON (a.id = b.id);
</pre><p>
Although this query's restrictions are superficially similar to the
previous example, the semantics are different because a row must be
emitted for each row of A that has no matching row in the join of B and C.
Therefore the planner has no choice of join order here: it must join
B to C and then join A to that result. Accordingly, this query takes
less time to plan than the previous query. In other cases, the planner
might be able to determine that more than one join order is safe.
For example, given:
</p><pre class="programlisting">
SELECT * FROM a LEFT JOIN b ON (a.bid = b.id) LEFT JOIN c ON (a.cid = c.id);
</pre><p>
it is valid to join A to either B or C first. Currently, only
<code class="literal">FULL JOIN</code> completely constrains the join order. Most
practical cases involving <code class="literal">LEFT JOIN</code> or <code class="literal">RIGHT JOIN</code>
can be rearranged to some extent.
</p><p>
Explicit inner join syntax (<code class="literal">INNER JOIN</code>, <code class="literal">CROSS
JOIN</code>, or unadorned <code class="literal">JOIN</code>) is semantically the same as
listing the input relations in <code class="literal">FROM</code>, so it does not
constrain the join order.
</p><p>
Even though most kinds of <code class="literal">JOIN</code> don't completely constrain
the join order, it is possible to instruct the
<span class="productname">PostgreSQL</span> query planner to treat all
<code class="literal">JOIN</code> clauses as constraining the join order anyway.
For example, these three queries are logically equivalent:
</p><pre class="programlisting">
SELECT * FROM a, b, c WHERE a.id = b.id AND b.ref = c.id;
SELECT * FROM a CROSS JOIN b CROSS JOIN c WHERE a.id = b.id AND b.ref = c.id;
SELECT * FROM a JOIN (b JOIN c ON (b.ref = c.id)) ON (a.id = b.id);
</pre><p>
But if we tell the planner to honor the <code class="literal">JOIN</code> order,
the second and third take less time to plan than the first. This effect
is not worth worrying about for only three tables, but it can be a
lifesaver with many tables.
</p><p>
To force the planner to follow the join order laid out by explicit
<code class="literal">JOIN</code>s,
set the <a class="xref" href="runtime-config-query.html#GUC-JOIN-COLLAPSE-LIMIT">join_collapse_limit</a> run-time parameter to 1.
(Other possible values are discussed below.)
</p><p>
You do not need to constrain the join order completely in order to
cut search time, because it's OK to use <code class="literal">JOIN</code> operators
within items of a plain <code class="literal">FROM</code> list. For example, consider:
</p><pre class="programlisting">
SELECT * FROM a CROSS JOIN b, c, d, e WHERE ...;
</pre><p>
With <code class="varname">join_collapse_limit</code> = 1, this
forces the planner to join A to B before joining them to other tables,
but doesn't constrain its choices otherwise. In this example, the
number of possible join orders is reduced by a factor of 5.
</p><p>
Constraining the planner's search in this way is a useful technique
both for reducing planning time and for directing the planner to a
good query plan. If the planner chooses a bad join order by default,
you can force it to choose a better order via <code class="literal">JOIN</code> syntax
— assuming that you know of a better order, that is. Experimentation
is recommended.
</p><p>
A closely related issue that affects planning time is collapsing of
subqueries into their parent query. For example, consider:
</p><pre class="programlisting">
SELECT *
FROM x, y,
(SELECT * FROM a, b, c WHERE something) AS ss
WHERE somethingelse;
</pre><p>
This situation might arise from use of a view that contains a join;
the view's <code class="literal">SELECT</code> rule will be inserted in place of the view
reference, yielding a query much like the above. Normally, the planner
will try to collapse the subquery into the parent, yielding:
</p><pre class="programlisting">
SELECT * FROM x, y, a, b, c WHERE something AND somethingelse;
</pre><p>
This usually results in a better plan than planning the subquery
separately. (For example, the outer <code class="literal">WHERE</code> conditions might be such that
joining X to A first eliminates many rows of A, thus avoiding the need to
form the full logical output of the subquery.) But at the same time,
we have increased the planning time; here, we have a five-way join
problem replacing two separate three-way join problems. Because of the
exponential growth of the number of possibilities, this makes a big
difference. The planner tries to avoid getting stuck in huge join search
problems by not collapsing a subquery if more than <code class="varname">from_collapse_limit</code>
<code class="literal">FROM</code> items would result in the parent
query. You can trade off planning time against quality of plan by
adjusting this run-time parameter up or down.
</p><p>
<a class="xref" href="runtime-config-query.html#GUC-FROM-COLLAPSE-LIMIT">from_collapse_limit</a> and <a class="xref" href="runtime-config-query.html#GUC-JOIN-COLLAPSE-LIMIT">join_collapse_limit</a>
are similarly named because they do almost the same thing: one controls
when the planner will <span class="quote">“<span class="quote">flatten out</span>”</span> subqueries, and the
other controls when it will flatten out explicit joins. Typically
you would either set <code class="varname">join_collapse_limit</code> equal to
<code class="varname">from_collapse_limit</code> (so that explicit joins and subqueries
act similarly) or set <code class="varname">join_collapse_limit</code> to 1 (if you want
to control join order with explicit joins). But you might set them
differently if you are trying to fine-tune the trade-off between planning
time and run time.
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