By default, a function is just a “black box” that the database system knows very little about the behavior of. However, that means that queries using the function may be executed much less efficiently than they could be. It is possible to supply additional knowledge that helps the planner optimize function calls.
Some basic facts can be supplied by declarative annotations provided in
the CREATE FUNCTION command. Most important of
these is the function's volatility
category (IMMUTABLE
, STABLE
,
or VOLATILE
); one should always be careful to
specify this correctly when defining a function.
The parallel safety property (PARALLEL
UNSAFE
, PARALLEL RESTRICTED
, or
PARALLEL SAFE
) must also be specified if you hope
to use the function in parallelized queries.
It can also be useful to specify the function's estimated execution
cost, and/or the number of rows a set-returning function is estimated
to return. However, the declarative way of specifying those two
facts only allows specifying a constant value, which is often
inadequate.
It is also possible to attach a planner support function to a SQL-callable function (called its target function), and thereby provide knowledge about the target function that is too complex to be represented declaratively. Planner support functions have to be written in C (although their target functions might not be), so this is an advanced feature that relatively few people will use.
A planner support function must have the SQL signature
supportfn(internal) returns internal
It is attached to its target function by specifying
the SUPPORT
clause when creating the target function.
The details of the API for planner support functions can be found in
file src/include/nodes/supportnodes.h
in the
PostgreSQL source code. Here we provide
just an overview of what planner support functions can do.
The set of possible requests to a support function is extensible,
so more things might be possible in future versions.
Some function calls can be simplified during planning based on
properties specific to the function. For example,
int4mul(n, 1)
could be simplified to
just n
. This type of transformation can be
performed by a planner support function, by having it implement
the SupportRequestSimplify
request type.
The support function will be called for each instance of its target
function found in a query parse tree. If it finds that the particular
call can be simplified into some other form, it can build and return a
parse tree representing that expression. This will automatically work
for operators based on the function, too — in the example just
given, n * 1
would also be simplified to
n
.
(But note that this is just an example; this particular
optimization is not actually performed by
standard PostgreSQL.)
We make no guarantee that PostgreSQL will
never call the target function in cases that the support function could
simplify. Ensure rigorous equivalence between the simplified
expression and an actual execution of the target function.
For target functions that return boolean
, it is often useful to estimate
the fraction of rows that will be selected by a WHERE
clause using that
function. This can be done by a support function that implements
the SupportRequestSelectivity
request type.
If the target function's run time is highly dependent on its inputs,
it may be useful to provide a non-constant cost estimate for it.
This can be done by a support function that implements
the SupportRequestCost
request type.
For target functions that return sets, it is often useful to provide
a non-constant estimate for the number of rows that will be returned.
This can be done by a support function that implements
the SupportRequestRows
request type.
For target functions that return boolean
, it may be possible to
convert a function call appearing in WHERE
into an indexable operator
clause or clauses. The converted clauses might be exactly equivalent
to the function's condition, or they could be somewhat weaker (that is,
they might accept some values that the function condition does not).
In the latter case the index condition is said to
be lossy; it can still be used to scan an index,
but the function call will have to be executed for each row returned by
the index to see if it really passes the WHERE
condition or not.
To create such conditions, the support function must implement
the SupportRequestIndexCondition
request type.