/*-------------------------------------------------------------------------
*
* supportnodes.h
* Definitions for planner support functions.
*
* This file defines the API for "planner support functions", which
* are SQL functions (normally written in C) that can be attached to
* another "target" function to give the system additional knowledge
* about the target function. All the current capabilities have to do
* with planning queries that use the target function, though it is
* possible that future extensions will add functionality to be invoked
* by the parser or executor.
*
* A support function must have the SQL signature
* supportfn(internal) returns internal
* The argument is a pointer to one of the Node types defined in this file.
* The result is usually also a Node pointer, though its type depends on
* which capability is being invoked. In all cases, a NULL pointer result
* (that's PG_RETURN_POINTER(NULL), not PG_RETURN_NULL()) indicates that
* the support function cannot do anything useful for the given request.
* Support functions must return a NULL pointer, not fail, if they do not
* recognize the request node type or cannot handle the given case; this
* allows for future extensions of the set of request cases.
*
*
* Portions Copyright (c) 1996-2023, PostgreSQL Global Development Group
* Portions Copyright (c) 1994, Regents of the University of California
*
* src/include/nodes/supportnodes.h
*
*-------------------------------------------------------------------------
*/
#ifndef SUPPORTNODES_H
#define SUPPORTNODES_H
#include "nodes/plannodes.h"
struct PlannerInfo; /* avoid including pathnodes.h here */
struct IndexOptInfo;
struct SpecialJoinInfo;
struct WindowClause;
/*
* The Simplify request allows the support function to perform plan-time
* simplification of a call to its target function. For example, a varchar
* length coercion that does not decrease the allowed length of its argument
* could be replaced by a RelabelType node, or "x + 0" could be replaced by
* "x". This is invoked during the planner's constant-folding pass, so the
* function's arguments can be presumed already simplified.
*
* The planner's PlannerInfo "root" is typically not needed, but can be
* consulted if it's necessary to obtain info about Vars present in
* the given node tree. Beware that root could be NULL in some usages.
*
* "fcall" will be a FuncExpr invoking the support function's target
* function. (This is true even if the original parsetree node was an
* operator call; a FuncExpr is synthesized for this purpose.)
*
* The result should be a semantically-equivalent transformed node tree,
* or NULL if no simplification could be performed. Do *not* return or
* modify *fcall, as it isn't really a separately allocated Node. But
* it's okay to use fcall->args, or parts of it, in the result tree.
*/
typedef struct SupportRequestSimplify
{
NodeTag type;
struct PlannerInfo *root; /* Planner's infrastructure */
FuncExpr *fcall; /* Function call to be simplified */
} SupportRequestSimplify;
/*
* The Selectivity request allows the support function to provide a
* selectivity estimate for a function appearing at top level of a WHERE
* clause (so it applies only to functions returning boolean).
*
* The input arguments are the same as are supplied to operator restriction
* and join estimators, except that we unify those two APIs into just one
* request type. See clause_selectivity() for the details.
*
* If an estimate can be made, store it into the "selectivity" field and
* return the address of the SupportRequestSelectivity node; the estimate
* must be between 0 and 1 inclusive. Return NULL if no estimate can be
* made (in which case the planner will fall back to a default estimate,
* traditionally 1/3).
*
* If the target function is being used as the implementation of an operator,
* the support function will not be used for this purpose; the operator's
* restriction or join estimator is consulted instead.
*/
typedef struct SupportRequestSelectivity
{
NodeTag type;
/* Input fields: */
struct PlannerInfo *root; /* Planner's infrastructure */
Oid funcid; /* function we are inquiring about */
List *args; /* pre-simplified arguments to function */
Oid inputcollid; /* function's input collation */
bool is_join; /* is this a join or restriction case? */
int varRelid; /* if restriction, RTI of target relation */
JoinType jointype; /* if join, outer join type */
struct SpecialJoinInfo *sjinfo; /* if outer join, info about join */
/* Output fields: */
Selectivity selectivity; /* returned selectivity estimate */
} SupportRequestSelectivity;
/*
* The Cost request allows the support function to provide an execution
* cost estimate for its target function. The cost estimate can include
* both a one-time (query startup) component and a per-execution component.
* The estimate should *not* include the costs of evaluating the target
* function's arguments, only the target function itself.
*
* The "node" argument is normally the parse node that is invoking the
* target function. This is a FuncExpr in the simplest case, but it could
* also be an OpExpr, DistinctExpr, NullIfExpr, or WindowFunc, or possibly
* other cases in future. NULL is passed if the function cannot presume
* its arguments to be equivalent to what the calling node presents as
* arguments; that happens for, e.g., aggregate support functions and
* per-column comparison operators used by RowExprs.
*
* If an estimate can be made, store it into the cost fields and return the
* address of the SupportRequestCost node. Return NULL if no estimate can be
* made, in which case the planner will rely on the target function's procost
* field. (Note: while procost is automatically scaled by cpu_operator_cost,
* this is not the case for the outputs of the Cost request; the support
* function must scale its results appropriately on its own.)
*/
typedef struct SupportRequestCost
{
NodeTag type;
/* Input fields: */
struct PlannerInfo *root; /* Planner's infrastructure (could be NULL) */
Oid funcid; /* function we are inquiring about */
Node *node; /* parse node invoking function, or NULL */
/* Output fields: */
Cost startup; /* one-time cost */
Cost per_tuple; /* per-evaluation cost */
} SupportRequestCost;
/*
* The Rows request allows the support function to provide an output rowcount
* estimate for its target function (so it applies only to set-returning
* functions).
*
* The "node" argument is the parse node that is invoking the target function;
* currently this will always be a FuncExpr or OpExpr.
*
* If an estimate can be made, store it into the rows field and return the
* address of the SupportRequestRows node. Return NULL if no estimate can be
* made, in which case the planner will rely on the target function's prorows
* field.
*/
typedef struct SupportRequestRows
{
NodeTag type;
/* Input fields: */
struct PlannerInfo *root; /* Planner's infrastructure (could be NULL) */
Oid funcid; /* function we are inquiring about */
Node *node; /* parse node invoking function */
/* Output fields: */
double rows; /* number of rows expected to be returned */
} SupportRequestRows;
/*
* The IndexCondition request allows the support function to generate
* a directly-indexable condition based on a target function call that is
* not itself indexable. The target function call must appear at the top
* level of WHERE or JOIN/ON, so this applies only to functions returning
* boolean.
*
* The "node" argument is the parse node that is invoking the target function;
* currently this will always be a FuncExpr or OpExpr. The call is made
* only if at least one function argument matches an index column's variable
* or expression. "indexarg" identifies the matching argument (it's the
* argument's zero-based index in the node's args list).
*
* If the transformation is possible, return a List of directly-indexable
* condition expressions, else return NULL. (A List is used because it's
* sometimes useful to generate more than one indexable condition, such as
* when a LIKE with constant prefix gives rise to both >= and < conditions.)
*
* "Directly indexable" means that the condition must be directly executable
* by the index machinery. Typically this means that it is a binary OpExpr
* with the index column value on the left, a pseudo-constant on the right,
* and an operator that is in the index column's operator family. Other
* possibilities include RowCompareExpr, ScalarArrayOpExpr, and NullTest,
* depending on the index type; but those seem less likely to be useful for
* derived index conditions. "Pseudo-constant" means that the right-hand
* expression must not contain any volatile functions, nor any Vars of the
* table the index is for; use is_pseudo_constant_for_index() to check this.
* (Note: if the passed "node" is an OpExpr, the core planner already verified
* that the non-indexkey operand is pseudo-constant; but when the "node"
* is a FuncExpr, it does not check, since it doesn't know which of the
* function's arguments you might need to use in an index comparison value.)
*
* In many cases, an index condition can be generated but it is weaker than
* the function condition itself; for example, a LIKE with a constant prefix
* can produce an index range check based on the prefix, but we still need
* to execute the LIKE operator to verify the rest of the pattern. We say
* that such an index condition is "lossy". When returning an index condition,
* you should set the "lossy" request field to true if the condition is lossy,
* or false if it is an exact equivalent of the function's result. The core
* code will initialize that field to true, which is the common case.
*
* It is important to verify that the index operator family is the correct
* one for the condition you want to generate. Core support functions tend
* to use the known OID of a built-in opfamily for this, but extensions need
* to work harder, since their OIDs aren't fixed. A possibly workable
* answer for an index on an extension datatype is to verify the index AM's
* OID instead, and then assume that there's only one relevant opclass for
* your datatype so the opfamily must be the right one. Generating OpExpr
* nodes may also require knowing extension datatype OIDs (often you can
* find these out by applying exprType() to a function argument) and
* operator OIDs (which you can look up using get_opfamily_member).
*/
typedef struct SupportRequestIndexCondition
{
NodeTag type;
/* Input fields: */
struct PlannerInfo *root; /* Planner's infrastructure */
Oid funcid; /* function we are inquiring about */
Node *node; /* parse node invoking function */
int indexarg; /* index of function arg matching indexcol */
struct IndexOptInfo *index; /* planner's info about target index */
int indexcol; /* index of target index column (0-based) */
Oid opfamily; /* index column's operator family */
Oid indexcollation; /* index column's collation */
/* Output fields: */
bool lossy; /* set to false if index condition is an exact
* equivalent of the function call */
} SupportRequestIndexCondition;
/* ----------
* To support more efficient query execution of any monotonically increasing
* and/or monotonically decreasing window functions, we support calling the
* window function's prosupport function passing along this struct whenever
* the planner sees an OpExpr qual directly reference a window function in a
* subquery. When the planner encounters this, we populate this struct and
* pass it along to the window function's prosupport function so that it can
* evaluate if the given WindowFunc is;
*
* a) monotonically increasing, or
* b) monotonically decreasing, or
* c) both monotonically increasing and decreasing, or
* d) none of the above.
*
* A function that is monotonically increasing can never return a value that
* is lower than a value returned in a "previous call". A monotonically
* decreasing function can never return a value higher than a value returned
* in a previous call. A function that is both must return the same value
* each time.
*
* We define "previous call" to mean a previous call to the same WindowFunc
* struct in the same window partition.
*
* row_number() is an example of a monotonically increasing function. The
* return value will be reset back to 1 in each new partition. An example of
* a monotonically increasing and decreasing function is COUNT(*) OVER ().
* Since there is no ORDER BY clause in this example, all rows in the
* partition are peers and all rows within the partition will be within the
* frame bound. Likewise for COUNT(*) OVER(ORDER BY a ROWS BETWEEN UNBOUNDED
* PRECEDING AND UNBOUNDED FOLLOWING).
*
* COUNT(*) OVER (ORDER BY a ROWS BETWEEN CURRENT ROW AND UNBOUNDED FOLLOWING)
* is an example of a monotonically decreasing function.
*
* Implementations must only concern themselves with the given WindowFunc
* being monotonic in a single partition.
*
* Inputs:
* 'window_func' is the pointer to the window function being called.
*
* 'window_clause' pointer to the WindowClause data. Support functions can
* use this to check frame bounds, etc.
*
* Outputs:
* 'monotonic' the resulting MonotonicFunction value for the given input
* window function and window clause.
* ----------
*/
typedef struct SupportRequestWFuncMonotonic
{
NodeTag type;
/* Input fields: */
WindowFunc *window_func; /* Pointer to the window function data */
struct WindowClause *window_clause; /* Pointer to the window clause data */
/* Output fields: */
MonotonicFunction monotonic;
} SupportRequestWFuncMonotonic;
/*
* Some WindowFunc behavior might not be affected by certain variations in
* the WindowClause's frameOptions. For example, row_number() is coded in
* such a way that the frame options don't change the returned row number.
* nodeWindowAgg.c will have less work to do if the ROWS option is used
* instead of the RANGE option as no check needs to be done for peer rows.
* Since RANGE is included in the default frame options, window functions
* such as row_number() might want to change that to ROW.
*
* Here we allow a WindowFunc's support function to determine which, if
* anything, can be changed about the WindowClause which the WindowFunc
* belongs to. Currently only the frameOptions can be modified. However,
* we may want to allow more optimizations in the future.
*
* The support function is responsible for ensuring the optimized version of
* the frameOptions doesn't affect the result of the window function. The
* planner is responsible for only changing the frame options when all
* WindowFuncs using this particular WindowClause agree on what the optimized
* version of the frameOptions are. If a particular WindowFunc being used
* does not have a support function then the planner will not make any changes
* to the WindowClause's frameOptions.
*
* 'window_func' and 'window_clause' are set by the planner before calling the
* support function so that the support function has these fields available.
* These may be required in order to determine which optimizations are
* possible.
*
* 'frameOptions' is set by the planner to WindowClause.frameOptions. The
* support function must only adjust this if optimizations are possible for
* the given WindowFunc.
*/
typedef struct SupportRequestOptimizeWindowClause
{
NodeTag type;
/* Input fields: */
WindowFunc *window_func; /* Pointer to the window function data */
struct WindowClause *window_clause; /* Pointer to the window clause data */
/* Input/Output fields: */
int frameOptions; /* New frameOptions, or left untouched if no
* optimizations are possible. */
} SupportRequestOptimizeWindowClause;
#endif /* SUPPORTNODES_H */