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postgres/src/backend/optimizer/path/indxpath.c
Tom Lane 9df8f903eb Fix some issues with improper placement of outer join clauses. 
After applying outer-join identity 3 in the forward direction,
it was possible for the planner to mistakenly apply a qual clause
from above the two outer joins at the now-lower join level.
This can give the wrong answer, since a value that would get nulled
by the now-upper join might not yet be null.

To fix, when we perform such a transformation, consider that the
now-lower join hasn't really completed the outer join it's nominally
responsible for and thus its relid set should not include that OJ's
relid (nor should its output Vars have that nullingrel bit set).
Instead we add those bits when the now-upper join is performed.
The existing rules for qual placement then suffice to prevent
higher qual clauses from dropping below the now-upper join.
There are a few complications from needing to consider transitive
closures in case multiple pushdowns have happened, but all in all
it's not a very complex patch.

This is all new logic (from 2489d76c4) so no need to back-patch.
The added test cases all have the same results as in v15.

Tom Lane and Richard Guo

Discussion: https://postgr.es/m/0b819232-4b50-f245-1c7d-c8c61bf41827@postgrespro.ru
2023-05-17 11:14:04 -04:00

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/*-------------------------------------------------------------------------
*
* indxpath.c
* Routines to determine which indexes are usable for scanning a
* given relation, and create Paths accordingly.
*
* Portions Copyright (c) 1996-2023, PostgreSQL Global Development Group
* Portions Copyright (c) 1994, Regents of the University of California
*
*
* IDENTIFICATION
* src/backend/optimizer/path/indxpath.c
*
*-------------------------------------------------------------------------
*/
#include "postgres.h"
#include <math.h>
#include "access/stratnum.h"
#include "access/sysattr.h"
#include "catalog/pg_am.h"
#include "catalog/pg_operator.h"
#include "catalog/pg_opfamily.h"
#include "catalog/pg_type.h"
#include "nodes/makefuncs.h"
#include "nodes/nodeFuncs.h"
#include "nodes/supportnodes.h"
#include "optimizer/cost.h"
#include "optimizer/optimizer.h"
#include "optimizer/pathnode.h"
#include "optimizer/paths.h"
#include "optimizer/prep.h"
#include "optimizer/restrictinfo.h"
#include "utils/lsyscache.h"
#include "utils/selfuncs.h"
/* XXX see PartCollMatchesExprColl */
#define IndexCollMatchesExprColl(idxcollation, exprcollation) \
((idxcollation) == InvalidOid || (idxcollation) == (exprcollation))
/* Whether we are looking for plain indexscan, bitmap scan, or either */
typedef enum
{
ST_INDEXSCAN, /* must support amgettuple */
ST_BITMAPSCAN, /* must support amgetbitmap */
ST_ANYSCAN /* either is okay */
} ScanTypeControl;
/* Data structure for collecting qual clauses that match an index */
typedef struct
{
bool nonempty; /* True if lists are not all empty */
/* Lists of IndexClause nodes, one list per index column */
List *indexclauses[INDEX_MAX_KEYS];
} IndexClauseSet;
/* Per-path data used within choose_bitmap_and() */
typedef struct
{
Path *path; /* IndexPath, BitmapAndPath, or BitmapOrPath */
List *quals; /* the WHERE clauses it uses */
List *preds; /* predicates of its partial index(es) */
Bitmapset *clauseids; /* quals+preds represented as a bitmapset */
bool unclassifiable; /* has too many quals+preds to process? */
} PathClauseUsage;
/* Callback argument for ec_member_matches_indexcol */
typedef struct
{
IndexOptInfo *index; /* index we're considering */
int indexcol; /* index column we want to match to */
} ec_member_matches_arg;
static void consider_index_join_clauses(PlannerInfo *root, RelOptInfo *rel,
IndexOptInfo *index,
IndexClauseSet *rclauseset,
IndexClauseSet *jclauseset,
IndexClauseSet *eclauseset,
List **bitindexpaths);
static void consider_index_join_outer_rels(PlannerInfo *root, RelOptInfo *rel,
IndexOptInfo *index,
IndexClauseSet *rclauseset,
IndexClauseSet *jclauseset,
IndexClauseSet *eclauseset,
List **bitindexpaths,
List *indexjoinclauses,
int considered_clauses,
List **considered_relids);
static void get_join_index_paths(PlannerInfo *root, RelOptInfo *rel,
IndexOptInfo *index,
IndexClauseSet *rclauseset,
IndexClauseSet *jclauseset,
IndexClauseSet *eclauseset,
List **bitindexpaths,
Relids relids,
List **considered_relids);
static bool eclass_already_used(EquivalenceClass *parent_ec, Relids oldrelids,
List *indexjoinclauses);
static void get_index_paths(PlannerInfo *root, RelOptInfo *rel,
IndexOptInfo *index, IndexClauseSet *clauses,
List **bitindexpaths);
static List *build_index_paths(PlannerInfo *root, RelOptInfo *rel,
IndexOptInfo *index, IndexClauseSet *clauses,
bool useful_predicate,
ScanTypeControl scantype,
bool *skip_nonnative_saop,
bool *skip_lower_saop);
static List *build_paths_for_OR(PlannerInfo *root, RelOptInfo *rel,
List *clauses, List *other_clauses);
static List *generate_bitmap_or_paths(PlannerInfo *root, RelOptInfo *rel,
List *clauses, List *other_clauses);
static Path *choose_bitmap_and(PlannerInfo *root, RelOptInfo *rel,
List *paths);
static int path_usage_comparator(const void *a, const void *b);
static Cost bitmap_scan_cost_est(PlannerInfo *root, RelOptInfo *rel,
Path *ipath);
static Cost bitmap_and_cost_est(PlannerInfo *root, RelOptInfo *rel,
List *paths);
static PathClauseUsage *classify_index_clause_usage(Path *path,
List **clauselist);
static void find_indexpath_quals(Path *bitmapqual, List **quals, List **preds);
static int find_list_position(Node *node, List **nodelist);
static bool check_index_only(RelOptInfo *rel, IndexOptInfo *index);
static double get_loop_count(PlannerInfo *root, Index cur_relid, Relids outer_relids);
static double adjust_rowcount_for_semijoins(PlannerInfo *root,
Index cur_relid,
Index outer_relid,
double rowcount);
static double approximate_joinrel_size(PlannerInfo *root, Relids relids);
static void match_restriction_clauses_to_index(PlannerInfo *root,
IndexOptInfo *index,
IndexClauseSet *clauseset);
static void match_join_clauses_to_index(PlannerInfo *root,
RelOptInfo *rel, IndexOptInfo *index,
IndexClauseSet *clauseset,
List **joinorclauses);
static void match_eclass_clauses_to_index(PlannerInfo *root,
IndexOptInfo *index,
IndexClauseSet *clauseset);
static void match_clauses_to_index(PlannerInfo *root,
List *clauses,
IndexOptInfo *index,
IndexClauseSet *clauseset);
static void match_clause_to_index(PlannerInfo *root,
RestrictInfo *rinfo,
IndexOptInfo *index,
IndexClauseSet *clauseset);
static IndexClause *match_clause_to_indexcol(PlannerInfo *root,
RestrictInfo *rinfo,
int indexcol,
IndexOptInfo *index);
static bool IsBooleanOpfamily(Oid opfamily);
static IndexClause *match_boolean_index_clause(PlannerInfo *root,
RestrictInfo *rinfo,
int indexcol, IndexOptInfo *index);
static IndexClause *match_opclause_to_indexcol(PlannerInfo *root,
RestrictInfo *rinfo,
int indexcol,
IndexOptInfo *index);
static IndexClause *match_funcclause_to_indexcol(PlannerInfo *root,
RestrictInfo *rinfo,
int indexcol,
IndexOptInfo *index);
static IndexClause *get_index_clause_from_support(PlannerInfo *root,
RestrictInfo *rinfo,
Oid funcid,
int indexarg,
int indexcol,
IndexOptInfo *index);
static IndexClause *match_saopclause_to_indexcol(PlannerInfo *root,
RestrictInfo *rinfo,
int indexcol,
IndexOptInfo *index);
static IndexClause *match_rowcompare_to_indexcol(PlannerInfo *root,
RestrictInfo *rinfo,
int indexcol,
IndexOptInfo *index);
static IndexClause *expand_indexqual_rowcompare(PlannerInfo *root,
RestrictInfo *rinfo,
int indexcol,
IndexOptInfo *index,
Oid expr_op,
bool var_on_left);
static void match_pathkeys_to_index(IndexOptInfo *index, List *pathkeys,
List **orderby_clauses_p,
List **clause_columns_p);
static Expr *match_clause_to_ordering_op(IndexOptInfo *index,
int indexcol, Expr *clause, Oid pk_opfamily);
static bool ec_member_matches_indexcol(PlannerInfo *root, RelOptInfo *rel,
EquivalenceClass *ec, EquivalenceMember *em,
void *arg);
/*
* create_index_paths()
* Generate all interesting index paths for the given relation.
* Candidate paths are added to the rel's pathlist (using add_path).
*
* To be considered for an index scan, an index must match one or more
* restriction clauses or join clauses from the query's qual condition,
* or match the query's ORDER BY condition, or have a predicate that
* matches the query's qual condition.
*
* There are two basic kinds of index scans. A "plain" index scan uses
* only restriction clauses (possibly none at all) in its indexqual,
* so it can be applied in any context. A "parameterized" index scan uses
* join clauses (plus restriction clauses, if available) in its indexqual.
* When joining such a scan to one of the relations supplying the other
* variables used in its indexqual, the parameterized scan must appear as
* the inner relation of a nestloop join; it can't be used on the outer side,
* nor in a merge or hash join. In that context, values for the other rels'
* attributes are available and fixed during any one scan of the indexpath.
*
* An IndexPath is generated and submitted to add_path() for each plain or
* parameterized index scan this routine deems potentially interesting for
* the current query.
*
* 'rel' is the relation for which we want to generate index paths
*
* Note: check_index_predicates() must have been run previously for this rel.
*
* Note: in cases involving LATERAL references in the relation's tlist, it's
* possible that rel->lateral_relids is nonempty. Currently, we include
* lateral_relids into the parameterization reported for each path, but don't
* take it into account otherwise. The fact that any such rels *must* be
* available as parameter sources perhaps should influence our choices of
* index quals ... but for now, it doesn't seem worth troubling over.
* In particular, comments below about "unparameterized" paths should be read
* as meaning "unparameterized so far as the indexquals are concerned".
*/
void
create_index_paths(PlannerInfo *root, RelOptInfo *rel)
{
List *indexpaths;
List *bitindexpaths;
List *bitjoinpaths;
List *joinorclauses;
IndexClauseSet rclauseset;
IndexClauseSet jclauseset;
IndexClauseSet eclauseset;
ListCell *lc;
/* Skip the whole mess if no indexes */
if (rel->indexlist == NIL)
return;
/* Bitmap paths are collected and then dealt with at the end */
bitindexpaths = bitjoinpaths = joinorclauses = NIL;
/* Examine each index in turn */
foreach(lc, rel->indexlist)
{
IndexOptInfo *index = (IndexOptInfo *) lfirst(lc);
/* Protect limited-size array in IndexClauseSets */
Assert(index->nkeycolumns <= INDEX_MAX_KEYS);
/*
* Ignore partial indexes that do not match the query.
* (generate_bitmap_or_paths() might be able to do something with
* them, but that's of no concern here.)
*/
if (index->indpred != NIL && !index->predOK)
continue;
/*
* Identify the restriction clauses that can match the index.
*/
MemSet(&rclauseset, 0, sizeof(rclauseset));
match_restriction_clauses_to_index(root, index, &rclauseset);
/*
* Build index paths from the restriction clauses. These will be
* non-parameterized paths. Plain paths go directly to add_path(),
* bitmap paths are added to bitindexpaths to be handled below.
*/
get_index_paths(root, rel, index, &rclauseset,
&bitindexpaths);
/*
* Identify the join clauses that can match the index. For the moment
* we keep them separate from the restriction clauses. Note that this
* step finds only "loose" join clauses that have not been merged into
* EquivalenceClasses. Also, collect join OR clauses for later.
*/
MemSet(&jclauseset, 0, sizeof(jclauseset));
match_join_clauses_to_index(root, rel, index,
&jclauseset, &joinorclauses);
/*
* Look for EquivalenceClasses that can generate joinclauses matching
* the index.
*/
MemSet(&eclauseset, 0, sizeof(eclauseset));
match_eclass_clauses_to_index(root, index,
&eclauseset);
/*
* If we found any plain or eclass join clauses, build parameterized
* index paths using them.
*/
if (jclauseset.nonempty || eclauseset.nonempty)
consider_index_join_clauses(root, rel, index,
&rclauseset,
&jclauseset,
&eclauseset,
&bitjoinpaths);
}
/*
* Generate BitmapOrPaths for any suitable OR-clauses present in the
* restriction list. Add these to bitindexpaths.
*/
indexpaths = generate_bitmap_or_paths(root, rel,
rel->baserestrictinfo, NIL);
bitindexpaths = list_concat(bitindexpaths, indexpaths);
/*
* Likewise, generate BitmapOrPaths for any suitable OR-clauses present in
* the joinclause list. Add these to bitjoinpaths.
*/
indexpaths = generate_bitmap_or_paths(root, rel,
joinorclauses, rel->baserestrictinfo);
bitjoinpaths = list_concat(bitjoinpaths, indexpaths);
/*
* If we found anything usable, generate a BitmapHeapPath for the most
* promising combination of restriction bitmap index paths. Note there
* will be only one such path no matter how many indexes exist. This
* should be sufficient since there's basically only one figure of merit
* (total cost) for such a path.
*/
if (bitindexpaths != NIL)
{
Path *bitmapqual;
BitmapHeapPath *bpath;
bitmapqual = choose_bitmap_and(root, rel, bitindexpaths);
bpath = create_bitmap_heap_path(root, rel, bitmapqual,
rel->lateral_relids, 1.0, 0);
add_path(rel, (Path *) bpath);
/* create a partial bitmap heap path */
if (rel->consider_parallel && rel->lateral_relids == NULL)
create_partial_bitmap_paths(root, rel, bitmapqual);
}
/*
* Likewise, if we found anything usable, generate BitmapHeapPaths for the
* most promising combinations of join bitmap index paths. Our strategy
* is to generate one such path for each distinct parameterization seen
* among the available bitmap index paths. This may look pretty
* expensive, but usually there won't be very many distinct
* parameterizations. (This logic is quite similar to that in
* consider_index_join_clauses, but we're working with whole paths not
* individual clauses.)
*/
if (bitjoinpaths != NIL)
{
List *all_path_outers;
/* Identify each distinct parameterization seen in bitjoinpaths */
all_path_outers = NIL;
foreach(lc, bitjoinpaths)
{
Path *path = (Path *) lfirst(lc);
Relids required_outer = PATH_REQ_OUTER(path);
all_path_outers = list_append_unique(all_path_outers,
required_outer);
}
/* Now, for each distinct parameterization set ... */
foreach(lc, all_path_outers)
{
Relids max_outers = (Relids) lfirst(lc);
List *this_path_set;
Path *bitmapqual;
Relids required_outer;
double loop_count;
BitmapHeapPath *bpath;
ListCell *lcp;
/* Identify all the bitmap join paths needing no more than that */
this_path_set = NIL;
foreach(lcp, bitjoinpaths)
{
Path *path = (Path *) lfirst(lcp);
if (bms_is_subset(PATH_REQ_OUTER(path), max_outers))
this_path_set = lappend(this_path_set, path);
}
/*
* Add in restriction bitmap paths, since they can be used
* together with any join paths.
*/
this_path_set = list_concat(this_path_set, bitindexpaths);
/* Select best AND combination for this parameterization */
bitmapqual = choose_bitmap_and(root, rel, this_path_set);
/* And push that path into the mix */
required_outer = PATH_REQ_OUTER(bitmapqual);
loop_count = get_loop_count(root, rel->relid, required_outer);
bpath = create_bitmap_heap_path(root, rel, bitmapqual,
required_outer, loop_count, 0);
add_path(rel, (Path *) bpath);
}
}
}
/*
* consider_index_join_clauses
* Given sets of join clauses for an index, decide which parameterized
* index paths to build.
*
* Plain indexpaths are sent directly to add_path, while potential
* bitmap indexpaths are added to *bitindexpaths for later processing.
*
* 'rel' is the index's heap relation
* 'index' is the index for which we want to generate paths
* 'rclauseset' is the collection of indexable restriction clauses
* 'jclauseset' is the collection of indexable simple join clauses
* 'eclauseset' is the collection of indexable clauses from EquivalenceClasses
* '*bitindexpaths' is the list to add bitmap paths to
*/
static void
consider_index_join_clauses(PlannerInfo *root, RelOptInfo *rel,
IndexOptInfo *index,
IndexClauseSet *rclauseset,
IndexClauseSet *jclauseset,
IndexClauseSet *eclauseset,
List **bitindexpaths)
{
int considered_clauses = 0;
List *considered_relids = NIL;
int indexcol;
/*
* The strategy here is to identify every potentially useful set of outer
* rels that can provide indexable join clauses. For each such set,
* select all the join clauses available from those outer rels, add on all
* the indexable restriction clauses, and generate plain and/or bitmap
* index paths for that set of clauses. This is based on the assumption
* that it's always better to apply a clause as an indexqual than as a
* filter (qpqual); which is where an available clause would end up being
* applied if we omit it from the indexquals.
*
* This looks expensive, but in most practical cases there won't be very
* many distinct sets of outer rels to consider. As a safety valve when
* that's not true, we use a heuristic: limit the number of outer rel sets
* considered to a multiple of the number of clauses considered. (We'll
* always consider using each individual join clause, though.)
*
* For simplicity in selecting relevant clauses, we represent each set of
* outer rels as a maximum set of clause_relids --- that is, the indexed
* relation itself is also included in the relids set. considered_relids
* lists all relids sets we've already tried.
*/
for (indexcol = 0; indexcol < index->nkeycolumns; indexcol++)
{
/* Consider each applicable simple join clause */
considered_clauses += list_length(jclauseset->indexclauses[indexcol]);
consider_index_join_outer_rels(root, rel, index,
rclauseset, jclauseset, eclauseset,
bitindexpaths,
jclauseset->indexclauses[indexcol],
considered_clauses,
&considered_relids);
/* Consider each applicable eclass join clause */
considered_clauses += list_length(eclauseset->indexclauses[indexcol]);
consider_index_join_outer_rels(root, rel, index,
rclauseset, jclauseset, eclauseset,
bitindexpaths,
eclauseset->indexclauses[indexcol],
considered_clauses,
&considered_relids);
}
}
/*
* consider_index_join_outer_rels
* Generate parameterized paths based on clause relids in the clause list.
*
* Workhorse for consider_index_join_clauses; see notes therein for rationale.
*
* 'rel', 'index', 'rclauseset', 'jclauseset', 'eclauseset', and
* 'bitindexpaths' as above
* 'indexjoinclauses' is a list of IndexClauses for join clauses
* 'considered_clauses' is the total number of clauses considered (so far)
* '*considered_relids' is a list of all relids sets already considered
*/
static void
consider_index_join_outer_rels(PlannerInfo *root, RelOptInfo *rel,
IndexOptInfo *index,
IndexClauseSet *rclauseset,
IndexClauseSet *jclauseset,
IndexClauseSet *eclauseset,
List **bitindexpaths,
List *indexjoinclauses,
int considered_clauses,
List **considered_relids)
{
ListCell *lc;
/* Examine relids of each joinclause in the given list */
foreach(lc, indexjoinclauses)
{
IndexClause *iclause = (IndexClause *) lfirst(lc);
Relids clause_relids = iclause->rinfo->clause_relids;
EquivalenceClass *parent_ec = iclause->rinfo->parent_ec;
int num_considered_relids;
/* If we already tried its relids set, no need to do so again */
if (list_member(*considered_relids, clause_relids))
continue;
/*
* Generate the union of this clause's relids set with each
* previously-tried set. This ensures we try this clause along with
* every interesting subset of previous clauses. However, to avoid
* exponential growth of planning time when there are many clauses,
* limit the number of relid sets accepted to 10 * considered_clauses.
*
* Note: get_join_index_paths appends entries to *considered_relids,
* but we do not need to visit such newly-added entries within this
* loop, so we don't use foreach() here. No real harm would be done
* if we did visit them, since the subset check would reject them; but
* it would waste some cycles.
*/
num_considered_relids = list_length(*considered_relids);
for (int pos = 0; pos < num_considered_relids; pos++)
{
Relids oldrelids = (Relids) list_nth(*considered_relids, pos);
/*
* If either is a subset of the other, no new set is possible.
* This isn't a complete test for redundancy, but it's easy and
* cheap. get_join_index_paths will check more carefully if we
* already generated the same relids set.
*/
if (bms_subset_compare(clause_relids, oldrelids) != BMS_DIFFERENT)
continue;
/*
* If this clause was derived from an equivalence class, the
* clause list may contain other clauses derived from the same
* eclass. We should not consider that combining this clause with
* one of those clauses generates a usefully different
* parameterization; so skip if any clause derived from the same
* eclass would already have been included when using oldrelids.
*/
if (parent_ec &&
eclass_already_used(parent_ec, oldrelids,
indexjoinclauses))
continue;
/*
* If the number of relid sets considered exceeds our heuristic
* limit, stop considering combinations of clauses. We'll still
* consider the current clause alone, though (below this loop).
*/
if (list_length(*considered_relids) >= 10 * considered_clauses)
break;
/* OK, try the union set */
get_join_index_paths(root, rel, index,
rclauseset, jclauseset, eclauseset,
bitindexpaths,
bms_union(clause_relids, oldrelids),
considered_relids);
}
/* Also try this set of relids by itself */
get_join_index_paths(root, rel, index,
rclauseset, jclauseset, eclauseset,
bitindexpaths,
clause_relids,
considered_relids);
}
}
/*
* get_join_index_paths
* Generate index paths using clauses from the specified outer relations.
* In addition to generating paths, relids is added to *considered_relids
* if not already present.
*
* Workhorse for consider_index_join_clauses; see notes therein for rationale.
*
* 'rel', 'index', 'rclauseset', 'jclauseset', 'eclauseset',
* 'bitindexpaths', 'considered_relids' as above
* 'relids' is the current set of relids to consider (the target rel plus
* one or more outer rels)
*/
static void
get_join_index_paths(PlannerInfo *root, RelOptInfo *rel,
IndexOptInfo *index,
IndexClauseSet *rclauseset,
IndexClauseSet *jclauseset,
IndexClauseSet *eclauseset,
List **bitindexpaths,
Relids relids,
List **considered_relids)
{
IndexClauseSet clauseset;
int indexcol;
/* If we already considered this relids set, don't repeat the work */
if (list_member(*considered_relids, relids))
return;
/* Identify indexclauses usable with this relids set */
MemSet(&clauseset, 0, sizeof(clauseset));
for (indexcol = 0; indexcol < index->nkeycolumns; indexcol++)
{
ListCell *lc;
/* First find applicable simple join clauses */
foreach(lc, jclauseset->indexclauses[indexcol])
{
IndexClause *iclause = (IndexClause *) lfirst(lc);
if (bms_is_subset(iclause->rinfo->clause_relids, relids))
clauseset.indexclauses[indexcol] =
lappend(clauseset.indexclauses[indexcol], iclause);
}
/*
* Add applicable eclass join clauses. The clauses generated for each
* column are redundant (cf generate_implied_equalities_for_column),
* so we need at most one. This is the only exception to the general
* rule of using all available index clauses.
*/
foreach(lc, eclauseset->indexclauses[indexcol])
{
IndexClause *iclause = (IndexClause *) lfirst(lc);
if (bms_is_subset(iclause->rinfo->clause_relids, relids))
{
clauseset.indexclauses[indexcol] =
lappend(clauseset.indexclauses[indexcol], iclause);
break;
}
}
/* Add restriction clauses */
clauseset.indexclauses[indexcol] =
list_concat(clauseset.indexclauses[indexcol],
rclauseset->indexclauses[indexcol]);
if (clauseset.indexclauses[indexcol] != NIL)
clauseset.nonempty = true;
}
/* We should have found something, else caller passed silly relids */
Assert(clauseset.nonempty);
/* Build index path(s) using the collected set of clauses */
get_index_paths(root, rel, index, &clauseset, bitindexpaths);
/*
* Remember we considered paths for this set of relids.
*/
*considered_relids = lappend(*considered_relids, relids);
}
/*
* eclass_already_used
* True if any join clause usable with oldrelids was generated from
* the specified equivalence class.
*/
static bool
eclass_already_used(EquivalenceClass *parent_ec, Relids oldrelids,
List *indexjoinclauses)
{
ListCell *lc;
foreach(lc, indexjoinclauses)
{
IndexClause *iclause = (IndexClause *) lfirst(lc);
RestrictInfo *rinfo = iclause->rinfo;
if (rinfo->parent_ec == parent_ec &&
bms_is_subset(rinfo->clause_relids, oldrelids))
return true;
}
return false;
}
/*
* get_index_paths
* Given an index and a set of index clauses for it, construct IndexPaths.
*
* Plain indexpaths are sent directly to add_path, while potential
* bitmap indexpaths are added to *bitindexpaths for later processing.
*
* This is a fairly simple frontend to build_index_paths(). Its reason for
* existence is mainly to handle ScalarArrayOpExpr quals properly. If the
* index AM supports them natively, we should just include them in simple
* index paths. If not, we should exclude them while building simple index
* paths, and then make a separate attempt to include them in bitmap paths.
* Furthermore, we should consider excluding lower-order ScalarArrayOpExpr
* quals so as to create ordered paths.
*/
static void
get_index_paths(PlannerInfo *root, RelOptInfo *rel,
IndexOptInfo *index, IndexClauseSet *clauses,
List **bitindexpaths)
{
List *indexpaths;
bool skip_nonnative_saop = false;
bool skip_lower_saop = false;
ListCell *lc;
/*
* Build simple index paths using the clauses. Allow ScalarArrayOpExpr
* clauses only if the index AM supports them natively, and skip any such
* clauses for index columns after the first (so that we produce ordered
* paths if possible).
*/
indexpaths = build_index_paths(root, rel,
index, clauses,
index->predOK,
ST_ANYSCAN,
&skip_nonnative_saop,
&skip_lower_saop);
/*
* If we skipped any lower-order ScalarArrayOpExprs on an index with an AM
* that supports them, then try again including those clauses. This will
* produce paths with more selectivity but no ordering.
*/
if (skip_lower_saop)
{
indexpaths = list_concat(indexpaths,
build_index_paths(root, rel,
index, clauses,
index->predOK,
ST_ANYSCAN,
&skip_nonnative_saop,
NULL));
}
/*
* Submit all the ones that can form plain IndexScan plans to add_path. (A
* plain IndexPath can represent either a plain IndexScan or an
* IndexOnlyScan, but for our purposes here that distinction does not
* matter. However, some of the indexes might support only bitmap scans,
* and those we mustn't submit to add_path here.)
*
* Also, pick out the ones that are usable as bitmap scans. For that, we
* must discard indexes that don't support bitmap scans, and we also are
* only interested in paths that have some selectivity; we should discard
* anything that was generated solely for ordering purposes.
*/
foreach(lc, indexpaths)
{
IndexPath *ipath = (IndexPath *) lfirst(lc);
if (index->amhasgettuple)
add_path(rel, (Path *) ipath);
if (index->amhasgetbitmap &&
(ipath->path.pathkeys == NIL ||
ipath->indexselectivity < 1.0))
*bitindexpaths = lappend(*bitindexpaths, ipath);
}
/*
* If there were ScalarArrayOpExpr clauses that the index can't handle
* natively, generate bitmap scan paths relying on executor-managed
* ScalarArrayOpExpr.
*/
if (skip_nonnative_saop)
{
indexpaths = build_index_paths(root, rel,
index, clauses,
false,
ST_BITMAPSCAN,
NULL,
NULL);
*bitindexpaths = list_concat(*bitindexpaths, indexpaths);
}
}
/*
* build_index_paths
* Given an index and a set of index clauses for it, construct zero
* or more IndexPaths. It also constructs zero or more partial IndexPaths.
*
* We return a list of paths because (1) this routine checks some cases
* that should cause us to not generate any IndexPath, and (2) in some
* cases we want to consider both a forward and a backward scan, so as
* to obtain both sort orders. Note that the paths are just returned
* to the caller and not immediately fed to add_path().
*
* At top level, useful_predicate should be exactly the index's predOK flag
* (ie, true if it has a predicate that was proven from the restriction
* clauses). When working on an arm of an OR clause, useful_predicate
* should be true if the predicate required the current OR list to be proven.
* Note that this routine should never be called at all if the index has an
* unprovable predicate.
*
* scantype indicates whether we want to create plain indexscans, bitmap
* indexscans, or both. When it's ST_BITMAPSCAN, we will not consider
* index ordering while deciding if a Path is worth generating.
*
* If skip_nonnative_saop is non-NULL, we ignore ScalarArrayOpExpr clauses
* unless the index AM supports them directly, and we set *skip_nonnative_saop
* to true if we found any such clauses (caller must initialize the variable
* to false). If it's NULL, we do not ignore ScalarArrayOpExpr clauses.
*
* If skip_lower_saop is non-NULL, we ignore ScalarArrayOpExpr clauses for
* non-first index columns, and we set *skip_lower_saop to true if we found
* any such clauses (caller must initialize the variable to false). If it's
* NULL, we do not ignore non-first ScalarArrayOpExpr clauses, but they will
* result in considering the scan's output to be unordered.
*
* 'rel' is the index's heap relation
* 'index' is the index for which we want to generate paths
* 'clauses' is the collection of indexable clauses (IndexClause nodes)
* 'useful_predicate' indicates whether the index has a useful predicate
* 'scantype' indicates whether we need plain or bitmap scan support
* 'skip_nonnative_saop' indicates whether to accept SAOP if index AM doesn't
* 'skip_lower_saop' indicates whether to accept non-first-column SAOP
*/
static List *
build_index_paths(PlannerInfo *root, RelOptInfo *rel,
IndexOptInfo *index, IndexClauseSet *clauses,
bool useful_predicate,
ScanTypeControl scantype,
bool *skip_nonnative_saop,
bool *skip_lower_saop)
{
List *result = NIL;
IndexPath *ipath;
List *index_clauses;
Relids outer_relids;
double loop_count;
List *orderbyclauses;
List *orderbyclausecols;
List *index_pathkeys;
List *useful_pathkeys;
bool found_lower_saop_clause;
bool pathkeys_possibly_useful;
bool index_is_ordered;
bool index_only_scan;
int indexcol;
/*
* Check that index supports the desired scan type(s)
*/
switch (scantype)
{
case ST_INDEXSCAN:
if (!index->amhasgettuple)
return NIL;
break;
case ST_BITMAPSCAN:
if (!index->amhasgetbitmap)
return NIL;
break;
case ST_ANYSCAN:
/* either or both are OK */
break;
}
/*
* 1. Combine the per-column IndexClause lists into an overall list.
*
* In the resulting list, clauses are ordered by index key, so that the
* column numbers form a nondecreasing sequence. (This order is depended
* on by btree and possibly other places.) The list can be empty, if the
* index AM allows that.
*
* found_lower_saop_clause is set true if we accept a ScalarArrayOpExpr
* index clause for a non-first index column. This prevents us from
* assuming that the scan result is ordered. (Actually, the result is
* still ordered if there are equality constraints for all earlier
* columns, but it seems too expensive and non-modular for this code to be
* aware of that refinement.)
*
* We also build a Relids set showing which outer rels are required by the
* selected clauses. Any lateral_relids are included in that, but not
* otherwise accounted for.
*/
index_clauses = NIL;
found_lower_saop_clause = false;
outer_relids = bms_copy(rel->lateral_relids);
for (indexcol = 0; indexcol < index->nkeycolumns; indexcol++)
{
ListCell *lc;
foreach(lc, clauses->indexclauses[indexcol])
{
IndexClause *iclause = (IndexClause *) lfirst(lc);
RestrictInfo *rinfo = iclause->rinfo;
/* We might need to omit ScalarArrayOpExpr clauses */
if (IsA(rinfo->clause, ScalarArrayOpExpr))
{
if (!index->amsearcharray)
{
if (skip_nonnative_saop)
{
/* Ignore because not supported by index */
*skip_nonnative_saop = true;
continue;
}
/* Caller had better intend this only for bitmap scan */
Assert(scantype == ST_BITMAPSCAN);
}
if (indexcol > 0)
{
if (skip_lower_saop)
{
/* Caller doesn't want to lose index ordering */
*skip_lower_saop = true;
continue;
}
found_lower_saop_clause = true;
}
}
/* OK to include this clause */
index_clauses = lappend(index_clauses, iclause);
outer_relids = bms_add_members(outer_relids,
rinfo->clause_relids);
}
/*
* If no clauses match the first index column, check for amoptionalkey
* restriction. We can't generate a scan over an index with
* amoptionalkey = false unless there's at least one index clause.
* (When working on columns after the first, this test cannot fail. It
* is always okay for columns after the first to not have any
* clauses.)
*/
if (index_clauses == NIL && !index->amoptionalkey)
return NIL;
}
/* We do not want the index's rel itself listed in outer_relids */
outer_relids = bms_del_member(outer_relids, rel->relid);
/* Compute loop_count for cost estimation purposes */
loop_count = get_loop_count(root, rel->relid, outer_relids);
/*
* 2. Compute pathkeys describing index's ordering, if any, then see how
* many of them are actually useful for this query. This is not relevant
* if we are only trying to build bitmap indexscans, nor if we have to
* assume the scan is unordered.
*/
pathkeys_possibly_useful = (scantype != ST_BITMAPSCAN &&
!found_lower_saop_clause &&
has_useful_pathkeys(root, rel));
index_is_ordered = (index->sortopfamily != NULL);
if (index_is_ordered && pathkeys_possibly_useful)
{
index_pathkeys = build_index_pathkeys(root, index,
ForwardScanDirection);
useful_pathkeys = truncate_useless_pathkeys(root, rel,
index_pathkeys);
orderbyclauses = NIL;
orderbyclausecols = NIL;
}
else if (index->amcanorderbyop && pathkeys_possibly_useful)
{
/* see if we can generate ordering operators for query_pathkeys */
match_pathkeys_to_index(index, root->query_pathkeys,
&orderbyclauses,
&orderbyclausecols);
if (orderbyclauses)
useful_pathkeys = root->query_pathkeys;
else
useful_pathkeys = NIL;
}
else
{
useful_pathkeys = NIL;
orderbyclauses = NIL;
orderbyclausecols = NIL;
}
/*
* 3. Check if an index-only scan is possible. If we're not building
* plain indexscans, this isn't relevant since bitmap scans don't support
* index data retrieval anyway.
*/
index_only_scan = (scantype != ST_BITMAPSCAN &&
check_index_only(rel, index));
/*
* 4. Generate an indexscan path if there are relevant restriction clauses
* in the current clauses, OR the index ordering is potentially useful for
* later merging or final output ordering, OR the index has a useful
* predicate, OR an index-only scan is possible.
*/
if (index_clauses != NIL || useful_pathkeys != NIL || useful_predicate ||
index_only_scan)
{
ipath = create_index_path(root, index,
index_clauses,
orderbyclauses,
orderbyclausecols,
useful_pathkeys,
ForwardScanDirection,
index_only_scan,
outer_relids,
loop_count,
false);
result = lappend(result, ipath);
/*
* If appropriate, consider parallel index scan. We don't allow
* parallel index scan for bitmap index scans.
*/
if (index->amcanparallel &&
rel->consider_parallel && outer_relids == NULL &&
scantype != ST_BITMAPSCAN)
{
ipath = create_index_path(root, index,
index_clauses,
orderbyclauses,
orderbyclausecols,
useful_pathkeys,
ForwardScanDirection,
index_only_scan,
outer_relids,
loop_count,
true);
/*
* if, after costing the path, we find that it's not worth using
* parallel workers, just free it.
*/
if (ipath->path.parallel_workers > 0)
add_partial_path(rel, (Path *) ipath);
else
pfree(ipath);
}
}
/*
* 5. If the index is ordered, a backwards scan might be interesting.
*/
if (index_is_ordered && pathkeys_possibly_useful)
{
index_pathkeys = build_index_pathkeys(root, index,
BackwardScanDirection);
useful_pathkeys = truncate_useless_pathkeys(root, rel,
index_pathkeys);
if (useful_pathkeys != NIL)
{
ipath = create_index_path(root, index,
index_clauses,
NIL,
NIL,
useful_pathkeys,
BackwardScanDirection,
index_only_scan,
outer_relids,
loop_count,
false);
result = lappend(result, ipath);
/* If appropriate, consider parallel index scan */
if (index->amcanparallel &&
rel->consider_parallel && outer_relids == NULL &&
scantype != ST_BITMAPSCAN)
{
ipath = create_index_path(root, index,
index_clauses,
NIL,
NIL,
useful_pathkeys,
BackwardScanDirection,
index_only_scan,
outer_relids,
loop_count,
true);
/*
* if, after costing the path, we find that it's not worth
* using parallel workers, just free it.
*/
if (ipath->path.parallel_workers > 0)
add_partial_path(rel, (Path *) ipath);
else
pfree(ipath);
}
}
}
return result;
}
/*
* build_paths_for_OR
* Given a list of restriction clauses from one arm of an OR clause,
* construct all matching IndexPaths for the relation.
*
* Here we must scan all indexes of the relation, since a bitmap OR tree
* can use multiple indexes.
*
* The caller actually supplies two lists of restriction clauses: some
* "current" ones and some "other" ones. Both lists can be used freely
* to match keys of the index, but an index must use at least one of the
* "current" clauses to be considered usable. The motivation for this is
* examples like
* WHERE (x = 42) AND (... OR (y = 52 AND z = 77) OR ....)
* While we are considering the y/z subclause of the OR, we can use "x = 42"
* as one of the available index conditions; but we shouldn't match the
* subclause to any index on x alone, because such a Path would already have
* been generated at the upper level. So we could use an index on x,y,z
* or an index on x,y for the OR subclause, but not an index on just x.
* When dealing with a partial index, a match of the index predicate to
* one of the "current" clauses also makes the index usable.
*
* 'rel' is the relation for which we want to generate index paths
* 'clauses' is the current list of clauses (RestrictInfo nodes)
* 'other_clauses' is the list of additional upper-level clauses
*/
static List *
build_paths_for_OR(PlannerInfo *root, RelOptInfo *rel,
List *clauses, List *other_clauses)
{
List *result = NIL;
List *all_clauses = NIL; /* not computed till needed */
ListCell *lc;
foreach(lc, rel->indexlist)
{
IndexOptInfo *index = (IndexOptInfo *) lfirst(lc);
IndexClauseSet clauseset;
List *indexpaths;
bool useful_predicate;
/* Ignore index if it doesn't support bitmap scans */
if (!index->amhasgetbitmap)
continue;
/*
* Ignore partial indexes that do not match the query. If a partial
* index is marked predOK then we know it's OK. Otherwise, we have to
* test whether the added clauses are sufficient to imply the
* predicate. If so, we can use the index in the current context.
*
* We set useful_predicate to true iff the predicate was proven using
* the current set of clauses. This is needed to prevent matching a
* predOK index to an arm of an OR, which would be a legal but
* pointlessly inefficient plan. (A better plan will be generated by
* just scanning the predOK index alone, no OR.)
*/
useful_predicate = false;
if (index->indpred != NIL)
{
if (index->predOK)
{
/* Usable, but don't set useful_predicate */
}
else
{
/* Form all_clauses if not done already */
if (all_clauses == NIL)
all_clauses = list_concat_copy(clauses, other_clauses);
if (!predicate_implied_by(index->indpred, all_clauses, false))
continue; /* can't use it at all */
if (!predicate_implied_by(index->indpred, other_clauses, false))
useful_predicate = true;
}
}
/*
* Identify the restriction clauses that can match the index.
*/
MemSet(&clauseset, 0, sizeof(clauseset));
match_clauses_to_index(root, clauses, index, &clauseset);
/*
* If no matches so far, and the index predicate isn't useful, we
* don't want it.
*/
if (!clauseset.nonempty && !useful_predicate)
continue;
/*
* Add "other" restriction clauses to the clauseset.
*/
match_clauses_to_index(root, other_clauses, index, &clauseset);
/*
* Construct paths if possible.
*/
indexpaths = build_index_paths(root, rel,
index, &clauseset,
useful_predicate,
ST_BITMAPSCAN,
NULL,
NULL);
result = list_concat(result, indexpaths);
}
return result;
}
/*
* generate_bitmap_or_paths
* Look through the list of clauses to find OR clauses, and generate
* a BitmapOrPath for each one we can handle that way. Return a list
* of the generated BitmapOrPaths.
*
* other_clauses is a list of additional clauses that can be assumed true
* for the purpose of generating indexquals, but are not to be searched for
* ORs. (See build_paths_for_OR() for motivation.)
*/
static List *
generate_bitmap_or_paths(PlannerInfo *root, RelOptInfo *rel,
List *clauses, List *other_clauses)
{
List *result = NIL;
List *all_clauses;
ListCell *lc;
/*
* We can use both the current and other clauses as context for
* build_paths_for_OR; no need to remove ORs from the lists.
*/
all_clauses = list_concat_copy(clauses, other_clauses);
foreach(lc, clauses)
{
RestrictInfo *rinfo = lfirst_node(RestrictInfo, lc);
List *pathlist;
Path *bitmapqual;
ListCell *j;
/* Ignore RestrictInfos that aren't ORs */
if (!restriction_is_or_clause(rinfo))
continue;
/*
* We must be able to match at least one index to each of the arms of
* the OR, else we can't use it.
*/
pathlist = NIL;
foreach(j, ((BoolExpr *) rinfo->orclause)->args)
{
Node *orarg = (Node *) lfirst(j);
List *indlist;
/* OR arguments should be ANDs or sub-RestrictInfos */
if (is_andclause(orarg))
{
List *andargs = ((BoolExpr *) orarg)->args;
indlist = build_paths_for_OR(root, rel,
andargs,
all_clauses);
/* Recurse in case there are sub-ORs */
indlist = list_concat(indlist,
generate_bitmap_or_paths(root, rel,
andargs,
all_clauses));
}
else
{
RestrictInfo *ri = castNode(RestrictInfo, orarg);
List *orargs;
Assert(!restriction_is_or_clause(ri));
orargs = list_make1(ri);
indlist = build_paths_for_OR(root, rel,
orargs,
all_clauses);
}
/*
* If nothing matched this arm, we can't do anything with this OR
* clause.
*/
if (indlist == NIL)
{
pathlist = NIL;
break;
}
/*
* OK, pick the most promising AND combination, and add it to
* pathlist.
*/
bitmapqual = choose_bitmap_and(root, rel, indlist);
pathlist = lappend(pathlist, bitmapqual);
}
/*
* If we have a match for every arm, then turn them into a
* BitmapOrPath, and add to result list.
*/
if (pathlist != NIL)
{
bitmapqual = (Path *) create_bitmap_or_path(root, rel, pathlist);
result = lappend(result, bitmapqual);
}
}
return result;
}
/*
* choose_bitmap_and
* Given a nonempty list of bitmap paths, AND them into one path.
*
* This is a nontrivial decision since we can legally use any subset of the
* given path set. We want to choose a good tradeoff between selectivity
* and cost of computing the bitmap.
*
* The result is either a single one of the inputs, or a BitmapAndPath
* combining multiple inputs.
*/
static Path *
choose_bitmap_and(PlannerInfo *root, RelOptInfo *rel, List *paths)
{
int npaths = list_length(paths);
PathClauseUsage **pathinfoarray;
PathClauseUsage *pathinfo;
List *clauselist;
List *bestpaths = NIL;
Cost bestcost = 0;
int i,
j;
ListCell *l;
Assert(npaths > 0); /* else caller error */
if (npaths == 1)
return (Path *) linitial(paths); /* easy case */
/*
* In theory we should consider every nonempty subset of the given paths.
* In practice that seems like overkill, given the crude nature of the
* estimates, not to mention the possible effects of higher-level AND and
* OR clauses. Moreover, it's completely impractical if there are a large
* number of paths, since the work would grow as O(2^N).
*
* As a heuristic, we first check for paths using exactly the same sets of
* WHERE clauses + index predicate conditions, and reject all but the
* cheapest-to-scan in any such group. This primarily gets rid of indexes
* that include the interesting columns but also irrelevant columns. (In
* situations where the DBA has gone overboard on creating variant
* indexes, this can make for a very large reduction in the number of
* paths considered further.)
*
* We then sort the surviving paths with the cheapest-to-scan first, and
* for each path, consider using that path alone as the basis for a bitmap
* scan. Then we consider bitmap AND scans formed from that path plus
* each subsequent (higher-cost) path, adding on a subsequent path if it
* results in a reduction in the estimated total scan cost. This means we
* consider about O(N^2) rather than O(2^N) path combinations, which is
* quite tolerable, especially given than N is usually reasonably small
* because of the prefiltering step. The cheapest of these is returned.
*
* We will only consider AND combinations in which no two indexes use the
* same WHERE clause. This is a bit of a kluge: it's needed because
* costsize.c and clausesel.c aren't very smart about redundant clauses.
* They will usually double-count the redundant clauses, producing a
* too-small selectivity that makes a redundant AND step look like it
* reduces the total cost. Perhaps someday that code will be smarter and
* we can remove this limitation. (But note that this also defends
* against flat-out duplicate input paths, which can happen because
* match_join_clauses_to_index will find the same OR join clauses that
* extract_restriction_or_clauses has pulled OR restriction clauses out
* of.)
*
* For the same reason, we reject AND combinations in which an index
* predicate clause duplicates another clause. Here we find it necessary
* to be even stricter: we'll reject a partial index if any of its
* predicate clauses are implied by the set of WHERE clauses and predicate
* clauses used so far. This covers cases such as a condition "x = 42"
* used with a plain index, followed by a clauseless scan of a partial
* index "WHERE x >= 40 AND x < 50". The partial index has been accepted
* only because "x = 42" was present, and so allowing it would partially
* double-count selectivity. (We could use predicate_implied_by on
* regular qual clauses too, to have a more intelligent, but much more
* expensive, check for redundancy --- but in most cases simple equality
* seems to suffice.)
*/
/*
* Extract clause usage info and detect any paths that use exactly the
* same set of clauses; keep only the cheapest-to-scan of any such groups.
* The surviving paths are put into an array for qsort'ing.
*/
pathinfoarray = (PathClauseUsage **)
palloc(npaths * sizeof(PathClauseUsage *));
clauselist = NIL;
npaths = 0;
foreach(l, paths)
{
Path *ipath = (Path *) lfirst(l);
pathinfo = classify_index_clause_usage(ipath, &clauselist);
/* If it's unclassifiable, treat it as distinct from all others */
if (pathinfo->unclassifiable)
{
pathinfoarray[npaths++] = pathinfo;
continue;
}
for (i = 0; i < npaths; i++)
{
if (!pathinfoarray[i]->unclassifiable &&
bms_equal(pathinfo->clauseids, pathinfoarray[i]->clauseids))
break;
}
if (i < npaths)
{
/* duplicate clauseids, keep the cheaper one */
Cost ncost;
Cost ocost;
Selectivity nselec;
Selectivity oselec;
cost_bitmap_tree_node(pathinfo->path, &ncost, &nselec);
cost_bitmap_tree_node(pathinfoarray[i]->path, &ocost, &oselec);
if (ncost < ocost)
pathinfoarray[i] = pathinfo;
}
else
{
/* not duplicate clauseids, add to array */
pathinfoarray[npaths++] = pathinfo;
}
}
/* If only one surviving path, we're done */
if (npaths == 1)
return pathinfoarray[0]->path;
/* Sort the surviving paths by index access cost */
qsort(pathinfoarray, npaths, sizeof(PathClauseUsage *),
path_usage_comparator);
/*
* For each surviving index, consider it as an "AND group leader", and see
* whether adding on any of the later indexes results in an AND path with
* cheaper total cost than before. Then take the cheapest AND group.
*
* Note: paths that are either clauseless or unclassifiable will have
* empty clauseids, so that they will not be rejected by the clauseids
* filter here, nor will they cause later paths to be rejected by it.
*/
for (i = 0; i < npaths; i++)
{
Cost costsofar;
List *qualsofar;
Bitmapset *clauseidsofar;
pathinfo = pathinfoarray[i];
paths = list_make1(pathinfo->path);
costsofar = bitmap_scan_cost_est(root, rel, pathinfo->path);
qualsofar = list_concat_copy(pathinfo->quals, pathinfo->preds);
clauseidsofar = bms_copy(pathinfo->clauseids);
for (j = i + 1; j < npaths; j++)
{
Cost newcost;
pathinfo = pathinfoarray[j];
/* Check for redundancy */
if (bms_overlap(pathinfo->clauseids, clauseidsofar))
continue; /* consider it redundant */
if (pathinfo->preds)
{
bool redundant = false;
/* we check each predicate clause separately */
foreach(l, pathinfo->preds)
{
Node *np = (Node *) lfirst(l);
if (predicate_implied_by(list_make1(np), qualsofar, false))
{
redundant = true;
break; /* out of inner foreach loop */
}
}
if (redundant)
continue;
}
/* tentatively add new path to paths, so we can estimate cost */
paths = lappend(paths, pathinfo->path);
newcost = bitmap_and_cost_est(root, rel, paths);
if (newcost < costsofar)
{
/* keep new path in paths, update subsidiary variables */
costsofar = newcost;
qualsofar = list_concat(qualsofar, pathinfo->quals);
qualsofar = list_concat(qualsofar, pathinfo->preds);
clauseidsofar = bms_add_members(clauseidsofar,
pathinfo->clauseids);
}
else
{
/* reject new path, remove it from paths list */
paths = list_truncate(paths, list_length(paths) - 1);
}
}
/* Keep the cheapest AND-group (or singleton) */
if (i == 0 || costsofar < bestcost)
{
bestpaths = paths;
bestcost = costsofar;
}
/* some easy cleanup (we don't try real hard though) */
list_free(qualsofar);
}
if (list_length(bestpaths) == 1)
return (Path *) linitial(bestpaths); /* no need for AND */
return (Path *) create_bitmap_and_path(root, rel, bestpaths);
}
/* qsort comparator to sort in increasing index access cost order */
static int
path_usage_comparator(const void *a, const void *b)
{
PathClauseUsage *pa = *(PathClauseUsage *const *) a;
PathClauseUsage *pb = *(PathClauseUsage *const *) b;
Cost acost;
Cost bcost;
Selectivity aselec;
Selectivity bselec;
cost_bitmap_tree_node(pa->path, &acost, &aselec);
cost_bitmap_tree_node(pb->path, &bcost, &bselec);
/*
* If costs are the same, sort by selectivity.
*/
if (acost < bcost)
return -1;
if (acost > bcost)
return 1;
if (aselec < bselec)
return -1;
if (aselec > bselec)
return 1;
return 0;
}
/*
* Estimate the cost of actually executing a bitmap scan with a single
* index path (which could be a BitmapAnd or BitmapOr node).
*/
static Cost
bitmap_scan_cost_est(PlannerInfo *root, RelOptInfo *rel, Path *ipath)
{
BitmapHeapPath bpath;
/* Set up a dummy BitmapHeapPath */
bpath.path.type = T_BitmapHeapPath;
bpath.path.pathtype = T_BitmapHeapScan;
bpath.path.parent = rel;
bpath.path.pathtarget = rel->reltarget;
bpath.path.param_info = ipath->param_info;
bpath.path.pathkeys = NIL;
bpath.bitmapqual = ipath;
/*
* Check the cost of temporary path without considering parallelism.
* Parallel bitmap heap path will be considered at later stage.
*/
bpath.path.parallel_workers = 0;
/* Now we can do cost_bitmap_heap_scan */
cost_bitmap_heap_scan(&bpath.path, root, rel,
bpath.path.param_info,
ipath,
get_loop_count(root, rel->relid,
PATH_REQ_OUTER(ipath)));
return bpath.path.total_cost;
}
/*
* Estimate the cost of actually executing a BitmapAnd scan with the given
* inputs.
*/
static Cost
bitmap_and_cost_est(PlannerInfo *root, RelOptInfo *rel, List *paths)
{
BitmapAndPath *apath;
/*
* Might as well build a real BitmapAndPath here, as the work is slightly
* too complicated to be worth repeating just to save one palloc.
*/
apath = create_bitmap_and_path(root, rel, paths);
return bitmap_scan_cost_est(root, rel, (Path *) apath);
}
/*
* classify_index_clause_usage
* Construct a PathClauseUsage struct describing the WHERE clauses and
* index predicate clauses used by the given indexscan path.
* We consider two clauses the same if they are equal().
*
* At some point we might want to migrate this info into the Path data
* structure proper, but for the moment it's only needed within
* choose_bitmap_and().
*
* *clauselist is used and expanded as needed to identify all the distinct
* clauses seen across successive calls. Caller must initialize it to NIL
* before first call of a set.
*/
static PathClauseUsage *
classify_index_clause_usage(Path *path, List **clauselist)
{
PathClauseUsage *result;
Bitmapset *clauseids;
ListCell *lc;
result = (PathClauseUsage *) palloc(sizeof(PathClauseUsage));
result->path = path;
/* Recursively find the quals and preds used by the path */
result->quals = NIL;
result->preds = NIL;
find_indexpath_quals(path, &result->quals, &result->preds);
/*
* Some machine-generated queries have outlandish numbers of qual clauses.
* To avoid getting into O(N^2) behavior even in this preliminary
* classification step, we want to limit the number of entries we can
* accumulate in *clauselist. Treat any path with more than 100 quals +
* preds as unclassifiable, which will cause calling code to consider it
* distinct from all other paths.
*/
if (list_length(result->quals) + list_length(result->preds) > 100)
{
result->clauseids = NULL;
result->unclassifiable = true;
return result;
}
/* Build up a bitmapset representing the quals and preds */
clauseids = NULL;
foreach(lc, result->quals)
{
Node *node = (Node *) lfirst(lc);
clauseids = bms_add_member(clauseids,
find_list_position(node, clauselist));
}
foreach(lc, result->preds)
{
Node *node = (Node *) lfirst(lc);
clauseids = bms_add_member(clauseids,
find_list_position(node, clauselist));
}
result->clauseids = clauseids;
result->unclassifiable = false;
return result;
}
/*
* find_indexpath_quals
*
* Given the Path structure for a plain or bitmap indexscan, extract lists
* of all the index clauses and index predicate conditions used in the Path.
* These are appended to the initial contents of *quals and *preds (hence
* caller should initialize those to NIL).
*
* Note we are not trying to produce an accurate representation of the AND/OR
* semantics of the Path, but just find out all the base conditions used.
*
* The result lists contain pointers to the expressions used in the Path,
* but all the list cells are freshly built, so it's safe to destructively
* modify the lists (eg, by concat'ing with other lists).
*/
static void
find_indexpath_quals(Path *bitmapqual, List **quals, List **preds)
{
if (IsA(bitmapqual, BitmapAndPath))
{
BitmapAndPath *apath = (BitmapAndPath *) bitmapqual;
ListCell *l;
foreach(l, apath->bitmapquals)
{
find_indexpath_quals((Path *) lfirst(l), quals, preds);
}
}
else if (IsA(bitmapqual, BitmapOrPath))
{
BitmapOrPath *opath = (BitmapOrPath *) bitmapqual;
ListCell *l;
foreach(l, opath->bitmapquals)
{
find_indexpath_quals((Path *) lfirst(l), quals, preds);
}
}
else if (IsA(bitmapqual, IndexPath))
{
IndexPath *ipath = (IndexPath *) bitmapqual;
ListCell *l;
foreach(l, ipath->indexclauses)
{
IndexClause *iclause = (IndexClause *) lfirst(l);
*quals = lappend(*quals, iclause->rinfo->clause);
}
*preds = list_concat(*preds, ipath->indexinfo->indpred);
}
else
elog(ERROR, "unrecognized node type: %d", nodeTag(bitmapqual));
}
/*
* find_list_position
* Return the given node's position (counting from 0) in the given
* list of nodes. If it's not equal() to any existing list member,
* add it at the end, and return that position.
*/
static int
find_list_position(Node *node, List **nodelist)
{
int i;
ListCell *lc;
i = 0;
foreach(lc, *nodelist)
{
Node *oldnode = (Node *) lfirst(lc);
if (equal(node, oldnode))
return i;
i++;
}
*nodelist = lappend(*nodelist, node);
return i;
}
/*
* check_index_only
* Determine whether an index-only scan is possible for this index.
*/
static bool
check_index_only(RelOptInfo *rel, IndexOptInfo *index)
{
bool result;
Bitmapset *attrs_used = NULL;
Bitmapset *index_canreturn_attrs = NULL;
ListCell *lc;
int i;
/* Index-only scans must be enabled */
if (!enable_indexonlyscan)
return false;
/*
* Check that all needed attributes of the relation are available from the
* index.
*/
/*
* First, identify all the attributes needed for joins or final output.
* Note: we must look at rel's targetlist, not the attr_needed data,
* because attr_needed isn't computed for inheritance child rels.
*/
pull_varattnos((Node *) rel->reltarget->exprs, rel->relid, &attrs_used);
/*
* Add all the attributes used by restriction clauses; but consider only
* those clauses not implied by the index predicate, since ones that are
* so implied don't need to be checked explicitly in the plan.
*
* Note: attributes used only in index quals would not be needed at
* runtime either, if we are certain that the index is not lossy. However
* it'd be complicated to account for that accurately, and it doesn't
* matter in most cases, since we'd conclude that such attributes are
* available from the index anyway.
*/
foreach(lc, index->indrestrictinfo)
{
RestrictInfo *rinfo = (RestrictInfo *) lfirst(lc);
pull_varattnos((Node *) rinfo->clause, rel->relid, &attrs_used);
}
/*
* Construct a bitmapset of columns that the index can return back in an
* index-only scan.
*/
for (i = 0; i < index->ncolumns; i++)
{
int attno = index->indexkeys[i];
/*
* For the moment, we just ignore index expressions. It might be nice
* to do something with them, later.
*/
if (attno == 0)
continue;
if (index->canreturn[i])
index_canreturn_attrs =
bms_add_member(index_canreturn_attrs,
attno - FirstLowInvalidHeapAttributeNumber);
}
/* Do we have all the necessary attributes? */
result = bms_is_subset(attrs_used, index_canreturn_attrs);
bms_free(attrs_used);
bms_free(index_canreturn_attrs);
return result;
}
/*
* get_loop_count
* Choose the loop count estimate to use for costing a parameterized path
* with the given set of outer relids.
*
* Since we produce parameterized paths before we've begun to generate join
* relations, it's impossible to predict exactly how many times a parameterized
* path will be iterated; we don't know the size of the relation that will be
* on the outside of the nestloop. However, we should try to account for
* multiple iterations somehow in costing the path. The heuristic embodied
* here is to use the rowcount of the smallest other base relation needed in
* the join clauses used by the path. (We could alternatively consider the
* largest one, but that seems too optimistic.) This is of course the right
* answer for single-other-relation cases, and it seems like a reasonable
* zero-order approximation for multiway-join cases.
*
* In addition, we check to see if the other side of each join clause is on
* the inside of some semijoin that the current relation is on the outside of.
* If so, the only way that a parameterized path could be used is if the
* semijoin RHS has been unique-ified, so we should use the number of unique
* RHS rows rather than using the relation's raw rowcount.
*
* Note: for this to work, allpaths.c must establish all baserel size
* estimates before it begins to compute paths, or at least before it
* calls create_index_paths().
*/
static double
get_loop_count(PlannerInfo *root, Index cur_relid, Relids outer_relids)
{
double result;
int outer_relid;
/* For a non-parameterized path, just return 1.0 quickly */
if (outer_relids == NULL)
return 1.0;
result = 0.0;
outer_relid = -1;
while ((outer_relid = bms_next_member(outer_relids, outer_relid)) >= 0)
{
RelOptInfo *outer_rel;
double rowcount;
/* Paranoia: ignore bogus relid indexes */
if (outer_relid >= root->simple_rel_array_size)
continue;
outer_rel = root->simple_rel_array[outer_relid];
if (outer_rel == NULL)
continue;
Assert(outer_rel->relid == outer_relid); /* sanity check on array */
/* Other relation could be proven empty, if so ignore */
if (IS_DUMMY_REL(outer_rel))
continue;
/* Otherwise, rel's rows estimate should be valid by now */
Assert(outer_rel->rows > 0);
/* Check to see if rel is on the inside of any semijoins */
rowcount = adjust_rowcount_for_semijoins(root,
cur_relid,
outer_relid,
outer_rel->rows);
/* Remember smallest row count estimate among the outer rels */
if (result == 0.0 || result > rowcount)
result = rowcount;
}
/* Return 1.0 if we found no valid relations (shouldn't happen) */
return (result > 0.0) ? result : 1.0;
}
/*
* Check to see if outer_relid is on the inside of any semijoin that cur_relid
* is on the outside of. If so, replace rowcount with the estimated number of
* unique rows from the semijoin RHS (assuming that's smaller, which it might
* not be). The estimate is crude but it's the best we can do at this stage
* of the proceedings.
*/
static double
adjust_rowcount_for_semijoins(PlannerInfo *root,
Index cur_relid,
Index outer_relid,
double rowcount)
{
ListCell *lc;
foreach(lc, root->join_info_list)
{
SpecialJoinInfo *sjinfo = (SpecialJoinInfo *) lfirst(lc);
if (sjinfo->jointype == JOIN_SEMI &&
bms_is_member(cur_relid, sjinfo->syn_lefthand) &&
bms_is_member(outer_relid, sjinfo->syn_righthand))
{
/* Estimate number of unique-ified rows */
double nraw;
double nunique;
nraw = approximate_joinrel_size(root, sjinfo->syn_righthand);
nunique = estimate_num_groups(root,
sjinfo->semi_rhs_exprs,
nraw,
NULL,
NULL);
if (rowcount > nunique)
rowcount = nunique;
}
}
return rowcount;
}
/*
* Make an approximate estimate of the size of a joinrel.
*
* We don't have enough info at this point to get a good estimate, so we
* just multiply the base relation sizes together. Fortunately, this is
* the right answer anyway for the most common case with a single relation
* on the RHS of a semijoin. Also, estimate_num_groups() has only a weak
* dependency on its input_rows argument (it basically uses it as a clamp).
* So we might be able to get a fairly decent end result even with a severe
* overestimate of the RHS's raw size.
*/
static double
approximate_joinrel_size(PlannerInfo *root, Relids relids)
{
double rowcount = 1.0;
int relid;
relid = -1;
while ((relid = bms_next_member(relids, relid)) >= 0)
{
RelOptInfo *rel;
/* Paranoia: ignore bogus relid indexes */
if (relid >= root->simple_rel_array_size)
continue;
rel = root->simple_rel_array[relid];
if (rel == NULL)
continue;
Assert(rel->relid == relid); /* sanity check on array */
/* Relation could be proven empty, if so ignore */
if (IS_DUMMY_REL(rel))
continue;
/* Otherwise, rel's rows estimate should be valid by now */
Assert(rel->rows > 0);
/* Accumulate product */
rowcount *= rel->rows;
}
return rowcount;
}
/****************************************************************************
* ---- ROUTINES TO CHECK QUERY CLAUSES ----
****************************************************************************/
/*
* match_restriction_clauses_to_index
* Identify restriction clauses for the rel that match the index.
* Matching clauses are added to *clauseset.
*/
static void
match_restriction_clauses_to_index(PlannerInfo *root,
IndexOptInfo *index,
IndexClauseSet *clauseset)
{
/* We can ignore clauses that are implied by the index predicate */
match_clauses_to_index(root, index->indrestrictinfo, index, clauseset);
}
/*
* match_join_clauses_to_index
* Identify join clauses for the rel that match the index.
* Matching clauses are added to *clauseset.
* Also, add any potentially usable join OR clauses to *joinorclauses.
*/
static void
match_join_clauses_to_index(PlannerInfo *root,
RelOptInfo *rel, IndexOptInfo *index,
IndexClauseSet *clauseset,
List **joinorclauses)
{
ListCell *lc;
/* Scan the rel's join clauses */
foreach(lc, rel->joininfo)
{
RestrictInfo *rinfo = (RestrictInfo *) lfirst(lc);
/* Check if clause can be moved to this rel */
if (!join_clause_is_movable_to(rinfo, rel))
continue;
/* Potentially usable, so see if it matches the index or is an OR */
if (restriction_is_or_clause(rinfo))
*joinorclauses = lappend(*joinorclauses, rinfo);
else
match_clause_to_index(root, rinfo, index, clauseset);
}
}
/*
* match_eclass_clauses_to_index
* Identify EquivalenceClass join clauses for the rel that match the index.
* Matching clauses are added to *clauseset.
*/
static void
match_eclass_clauses_to_index(PlannerInfo *root, IndexOptInfo *index,
IndexClauseSet *clauseset)
{
int indexcol;
/* No work if rel is not in any such ECs */
if (!index->rel->has_eclass_joins)
return;
for (indexcol = 0; indexcol < index->nkeycolumns; indexcol++)
{
ec_member_matches_arg arg;
List *clauses;
/* Generate clauses, skipping any that join to lateral_referencers */
arg.index = index;
arg.indexcol = indexcol;
clauses = generate_implied_equalities_for_column(root,
index->rel,
ec_member_matches_indexcol,
(void *) &arg,
index->rel->lateral_referencers);
/*
* We have to check whether the results actually do match the index,
* since for non-btree indexes the EC's equality operators might not
* be in the index opclass (cf ec_member_matches_indexcol).
*/
match_clauses_to_index(root, clauses, index, clauseset);
}
}
/*
* match_clauses_to_index
* Perform match_clause_to_index() for each clause in a list.
* Matching clauses are added to *clauseset.
*/
static void
match_clauses_to_index(PlannerInfo *root,
List *clauses,
IndexOptInfo *index,
IndexClauseSet *clauseset)
{
ListCell *lc;
foreach(lc, clauses)
{
RestrictInfo *rinfo = lfirst_node(RestrictInfo, lc);
match_clause_to_index(root, rinfo, index, clauseset);
}
}
/*
* match_clause_to_index
* Test whether a qual clause can be used with an index.
*
* If the clause is usable, add an IndexClause entry for it to the appropriate
* list in *clauseset. (*clauseset must be initialized to zeroes before first
* call.)
*
* Note: in some circumstances we may find the same RestrictInfos coming from
* multiple places. Defend against redundant outputs by refusing to add a
* clause twice (pointer equality should be a good enough check for this).
*
* Note: it's possible that a badly-defined index could have multiple matching
* columns. We always select the first match if so; this avoids scenarios
* wherein we get an inflated idea of the index's selectivity by using the
* same clause multiple times with different index columns.
*/
static void
match_clause_to_index(PlannerInfo *root,
RestrictInfo *rinfo,
IndexOptInfo *index,
IndexClauseSet *clauseset)
{
int indexcol;
/*
* Never match pseudoconstants to indexes. (Normally a match could not
* happen anyway, since a pseudoconstant clause couldn't contain a Var,
* but what if someone builds an expression index on a constant? It's not
* totally unreasonable to do so with a partial index, either.)
*/
if (rinfo->pseudoconstant)
return;
/*
* If clause can't be used as an indexqual because it must wait till after
* some lower-security-level restriction clause, reject it.
*/
if (!restriction_is_securely_promotable(rinfo, index->rel))
return;
/* OK, check each index key column for a match */
for (indexcol = 0; indexcol < index->nkeycolumns; indexcol++)
{
IndexClause *iclause;
ListCell *lc;
/* Ignore duplicates */
foreach(lc, clauseset->indexclauses[indexcol])
{
iclause = (IndexClause *) lfirst(lc);
if (iclause->rinfo == rinfo)
return;
}
/* OK, try to match the clause to the index column */
iclause = match_clause_to_indexcol(root,
rinfo,
indexcol,
index);
if (iclause)
{
/* Success, so record it */
clauseset->indexclauses[indexcol] =
lappend(clauseset->indexclauses[indexcol], iclause);
clauseset->nonempty = true;
return;
}
}
}
/*
* match_clause_to_indexcol()
* Determine whether a restriction clause matches a column of an index,
* and if so, build an IndexClause node describing the details.
*
* To match an index normally, an operator clause:
*
* (1) must be in the form (indexkey op const) or (const op indexkey);
* and
* (2) must contain an operator which is in the index's operator family
* for this column; and
* (3) must match the collation of the index, if collation is relevant.
*
* Our definition of "const" is exceedingly liberal: we allow anything that
* doesn't involve a volatile function or a Var of the index's relation.
* In particular, Vars belonging to other relations of the query are
* accepted here, since a clause of that form can be used in a
* parameterized indexscan. It's the responsibility of higher code levels
* to manage restriction and join clauses appropriately.
*
* Note: we do need to check for Vars of the index's relation on the
* "const" side of the clause, since clauses like (a.f1 OP (b.f2 OP a.f3))
* are not processable by a parameterized indexscan on a.f1, whereas
* something like (a.f1 OP (b.f2 OP c.f3)) is.
*
* Presently, the executor can only deal with indexquals that have the
* indexkey on the left, so we can only use clauses that have the indexkey
* on the right if we can commute the clause to put the key on the left.
* We handle that by generating an IndexClause with the correctly-commuted
* opclause as a derived indexqual.
*
* If the index has a collation, the clause must have the same collation.
* For collation-less indexes, we assume it doesn't matter; this is
* necessary for cases like "hstore ? text", wherein hstore's operators
* don't care about collation but the clause will get marked with a
* collation anyway because of the text argument. (This logic is
* embodied in the macro IndexCollMatchesExprColl.)
*
* It is also possible to match RowCompareExpr clauses to indexes (but
* currently, only btree indexes handle this).
*
* It is also possible to match ScalarArrayOpExpr clauses to indexes, when
* the clause is of the form "indexkey op ANY (arrayconst)".
*
* For boolean indexes, it is also possible to match the clause directly
* to the indexkey; or perhaps the clause is (NOT indexkey).
*
* And, last but not least, some operators and functions can be processed
* to derive (typically lossy) indexquals from a clause that isn't in
* itself indexable. If we see that any operand of an OpExpr or FuncExpr
* matches the index key, and the function has a planner support function
* attached to it, we'll invoke the support function to see if such an
* indexqual can be built.
*
* 'rinfo' is the clause to be tested (as a RestrictInfo node).
* 'indexcol' is a column number of 'index' (counting from 0).
* 'index' is the index of interest.
*
* Returns an IndexClause if the clause can be used with this index key,
* or NULL if not.
*
* NOTE: returns NULL if clause is an OR or AND clause; it is the
* responsibility of higher-level routines to cope with those.
*/
static IndexClause *
match_clause_to_indexcol(PlannerInfo *root,
RestrictInfo *rinfo,
int indexcol,
IndexOptInfo *index)
{
IndexClause *iclause;
Expr *clause = rinfo->clause;
Oid opfamily;
Assert(indexcol < index->nkeycolumns);
/*
* Historically this code has coped with NULL clauses. That's probably
* not possible anymore, but we might as well continue to cope.
*/
if (clause == NULL)
return NULL;
/* First check for boolean-index cases. */
opfamily = index->opfamily[indexcol];
if (IsBooleanOpfamily(opfamily))
{
iclause = match_boolean_index_clause(root, rinfo, indexcol, index);
if (iclause)
return iclause;
}
/*
* Clause must be an opclause, funcclause, ScalarArrayOpExpr, or
* RowCompareExpr. Or, if the index supports it, we can handle IS
* NULL/NOT NULL clauses.
*/
if (IsA(clause, OpExpr))
{
return match_opclause_to_indexcol(root, rinfo, indexcol, index);
}
else if (IsA(clause, FuncExpr))
{
return match_funcclause_to_indexcol(root, rinfo, indexcol, index);
}
else if (IsA(clause, ScalarArrayOpExpr))
{
return match_saopclause_to_indexcol(root, rinfo, indexcol, index);
}
else if (IsA(clause, RowCompareExpr))
{
return match_rowcompare_to_indexcol(root, rinfo, indexcol, index);
}
else if (index->amsearchnulls && IsA(clause, NullTest))
{
NullTest *nt = (NullTest *) clause;
if (!nt->argisrow &&
match_index_to_operand((Node *) nt->arg, indexcol, index))
{
iclause = makeNode(IndexClause);
iclause->rinfo = rinfo;
iclause->indexquals = list_make1(rinfo);
iclause->lossy = false;
iclause->indexcol = indexcol;
iclause->indexcols = NIL;
return iclause;
}
}
return NULL;
}
/*
* IsBooleanOpfamily
* Detect whether an opfamily supports boolean equality as an operator.
*
* If the opfamily OID is in the range of built-in objects, we can rely
* on hard-wired knowledge of which built-in opfamilies support this.
* For extension opfamilies, there's no choice but to do a catcache lookup.
*/
static bool
IsBooleanOpfamily(Oid opfamily)
{
if (opfamily < FirstNormalObjectId)
return IsBuiltinBooleanOpfamily(opfamily);
else
return op_in_opfamily(BooleanEqualOperator, opfamily);
}
/*
* match_boolean_index_clause
* Recognize restriction clauses that can be matched to a boolean index.
*
* The idea here is that, for an index on a boolean column that supports the
* BooleanEqualOperator, we can transform a plain reference to the indexkey
* into "indexkey = true", or "NOT indexkey" into "indexkey = false", etc,
* so as to make the expression indexable using the index's "=" operator.
* Since Postgres 8.1, we must do this because constant simplification does
* the reverse transformation; without this code there'd be no way to use
* such an index at all.
*
* This should be called only when IsBooleanOpfamily() recognizes the
* index's operator family. We check to see if the clause matches the
* index's key, and if so, build a suitable IndexClause.
*/
static IndexClause *
match_boolean_index_clause(PlannerInfo *root,
RestrictInfo *rinfo,
int indexcol,
IndexOptInfo *index)
{
Node *clause = (Node *) rinfo->clause;
Expr *op = NULL;
/* Direct match? */
if (match_index_to_operand(clause, indexcol, index))
{
/* convert to indexkey = TRUE */
op = make_opclause(BooleanEqualOperator, BOOLOID, false,
(Expr *) clause,
(Expr *) makeBoolConst(true, false),
InvalidOid, InvalidOid);
}
/* NOT clause? */
else if (is_notclause(clause))
{
Node *arg = (Node *) get_notclausearg((Expr *) clause);
if (match_index_to_operand(arg, indexcol, index))
{
/* convert to indexkey = FALSE */
op = make_opclause(BooleanEqualOperator, BOOLOID, false,
(Expr *) arg,
(Expr *) makeBoolConst(false, false),
InvalidOid, InvalidOid);
}
}
/*
* Since we only consider clauses at top level of WHERE, we can convert
* indexkey IS TRUE and indexkey IS FALSE to index searches as well. The
* different meaning for NULL isn't important.
*/
else if (clause && IsA(clause, BooleanTest))
{
BooleanTest *btest = (BooleanTest *) clause;
Node *arg = (Node *) btest->arg;
if (btest->booltesttype == IS_TRUE &&
match_index_to_operand(arg, indexcol, index))
{
/* convert to indexkey = TRUE */
op = make_opclause(BooleanEqualOperator, BOOLOID, false,
(Expr *) arg,
(Expr *) makeBoolConst(true, false),
InvalidOid, InvalidOid);
}
else if (btest->booltesttype == IS_FALSE &&
match_index_to_operand(arg, indexcol, index))
{
/* convert to indexkey = FALSE */
op = make_opclause(BooleanEqualOperator, BOOLOID, false,
(Expr *) arg,
(Expr *) makeBoolConst(false, false),
InvalidOid, InvalidOid);
}
}
/*
* If we successfully made an operator clause from the given qual, we must
* wrap it in an IndexClause. It's not lossy.
*/
if (op)
{
IndexClause *iclause = makeNode(IndexClause);
iclause->rinfo = rinfo;
iclause->indexquals = list_make1(make_simple_restrictinfo(root, op));
iclause->lossy = false;
iclause->indexcol = indexcol;
iclause->indexcols = NIL;
return iclause;
}
return NULL;
}
/*
* match_opclause_to_indexcol()
* Handles the OpExpr case for match_clause_to_indexcol(),
* which see for comments.
*/
static IndexClause *
match_opclause_to_indexcol(PlannerInfo *root,
RestrictInfo *rinfo,
int indexcol,
IndexOptInfo *index)
{
IndexClause *iclause;
OpExpr *clause = (OpExpr *) rinfo->clause;
Node *leftop,
*rightop;
Oid expr_op;
Oid expr_coll;
Index index_relid;
Oid opfamily;
Oid idxcollation;
/*
* Only binary operators need apply. (In theory, a planner support
* function could do something with a unary operator, but it seems
* unlikely to be worth the cycles to check.)
*/
if (list_length(clause->args) != 2)
return NULL;
leftop = (Node *) linitial(clause->args);
rightop = (Node *) lsecond(clause->args);
expr_op = clause->opno;
expr_coll = clause->inputcollid;
index_relid = index->rel->relid;
opfamily = index->opfamily[indexcol];
idxcollation = index->indexcollations[indexcol];
/*
* Check for clauses of the form: (indexkey operator constant) or
* (constant operator indexkey). See match_clause_to_indexcol's notes
* about const-ness.
*
* Note that we don't ask the support function about clauses that don't
* have one of these forms. Again, in principle it might be possible to
* do something, but it seems unlikely to be worth the cycles to check.
*/
if (match_index_to_operand(leftop, indexcol, index) &&
!bms_is_member(index_relid, rinfo->right_relids) &&
!contain_volatile_functions(rightop))
{
if (IndexCollMatchesExprColl(idxcollation, expr_coll) &&
op_in_opfamily(expr_op, opfamily))
{
iclause = makeNode(IndexClause);
iclause->rinfo = rinfo;
iclause->indexquals = list_make1(rinfo);
iclause->lossy = false;
iclause->indexcol = indexcol;
iclause->indexcols = NIL;
return iclause;
}
/*
* If we didn't find a member of the index's opfamily, try the support
* function for the operator's underlying function.
*/
set_opfuncid(clause); /* make sure we have opfuncid */
return get_index_clause_from_support(root,
rinfo,
clause->opfuncid,
0, /* indexarg on left */
indexcol,
index);
}
if (match_index_to_operand(rightop, indexcol, index) &&
!bms_is_member(index_relid, rinfo->left_relids) &&
!contain_volatile_functions(leftop))
{
if (IndexCollMatchesExprColl(idxcollation, expr_coll))
{
Oid comm_op = get_commutator(expr_op);
if (OidIsValid(comm_op) &&
op_in_opfamily(comm_op, opfamily))
{
RestrictInfo *commrinfo;
/* Build a commuted OpExpr and RestrictInfo */
commrinfo = commute_restrictinfo(rinfo, comm_op);
/* Make an IndexClause showing that as a derived qual */
iclause = makeNode(IndexClause);
iclause->rinfo = rinfo;
iclause->indexquals = list_make1(commrinfo);
iclause->lossy = false;
iclause->indexcol = indexcol;
iclause->indexcols = NIL;
return iclause;
}
}
/*
* If we didn't find a member of the index's opfamily, try the support
* function for the operator's underlying function.
*/
set_opfuncid(clause); /* make sure we have opfuncid */
return get_index_clause_from_support(root,
rinfo,
clause->opfuncid,
1, /* indexarg on right */
indexcol,
index);
}
return NULL;
}
/*
* match_funcclause_to_indexcol()
* Handles the FuncExpr case for match_clause_to_indexcol(),
* which see for comments.
*/
static IndexClause *
match_funcclause_to_indexcol(PlannerInfo *root,
RestrictInfo *rinfo,
int indexcol,
IndexOptInfo *index)
{
FuncExpr *clause = (FuncExpr *) rinfo->clause;
int indexarg;
ListCell *lc;
/*
* We have no built-in intelligence about function clauses, but if there's
* a planner support function, it might be able to do something. But, to
* cut down on wasted planning cycles, only call the support function if
* at least one argument matches the target index column.
*
* Note that we don't insist on the other arguments being pseudoconstants;
* the support function has to check that. This is to allow cases where
* only some of the other arguments need to be included in the indexqual.
*/
indexarg = 0;
foreach(lc, clause->args)
{
Node *op = (Node *) lfirst(lc);
if (match_index_to_operand(op, indexcol, index))
{
return get_index_clause_from_support(root,
rinfo,
clause->funcid,
indexarg,
indexcol,
index);
}
indexarg++;
}
return NULL;
}
/*
* get_index_clause_from_support()
* If the function has a planner support function, try to construct
* an IndexClause using indexquals created by the support function.
*/
static IndexClause *
get_index_clause_from_support(PlannerInfo *root,
RestrictInfo *rinfo,
Oid funcid,
int indexarg,
int indexcol,
IndexOptInfo *index)
{
Oid prosupport = get_func_support(funcid);
SupportRequestIndexCondition req;
List *sresult;
if (!OidIsValid(prosupport))
return NULL;
req.type = T_SupportRequestIndexCondition;
req.root = root;
req.funcid = funcid;
req.node = (Node *) rinfo->clause;
req.indexarg = indexarg;
req.index = index;
req.indexcol = indexcol;
req.opfamily = index->opfamily[indexcol];
req.indexcollation = index->indexcollations[indexcol];
req.lossy = true; /* default assumption */
sresult = (List *)
DatumGetPointer(OidFunctionCall1(prosupport,
PointerGetDatum(&req)));
if (sresult != NIL)
{
IndexClause *iclause = makeNode(IndexClause);
List *indexquals = NIL;
ListCell *lc;
/*
* The support function API says it should just give back bare
* clauses, so here we must wrap each one in a RestrictInfo.
*/
foreach(lc, sresult)
{
Expr *clause = (Expr *) lfirst(lc);
indexquals = lappend(indexquals,
make_simple_restrictinfo(root, clause));
}
iclause->rinfo = rinfo;
iclause->indexquals = indexquals;
iclause->lossy = req.lossy;
iclause->indexcol = indexcol;
iclause->indexcols = NIL;
return iclause;
}
return NULL;
}
/*
* match_saopclause_to_indexcol()
* Handles the ScalarArrayOpExpr case for match_clause_to_indexcol(),
* which see for comments.
*/
static IndexClause *
match_saopclause_to_indexcol(PlannerInfo *root,
RestrictInfo *rinfo,
int indexcol,
IndexOptInfo *index)
{
ScalarArrayOpExpr *saop = (ScalarArrayOpExpr *) rinfo->clause;
Node *leftop,
*rightop;
Relids right_relids;
Oid expr_op;
Oid expr_coll;
Index index_relid;
Oid opfamily;
Oid idxcollation;
/* We only accept ANY clauses, not ALL */
if (!saop->useOr)
return NULL;
leftop = (Node *) linitial(saop->args);
rightop = (Node *) lsecond(saop->args);
right_relids = pull_varnos(root, rightop);
expr_op = saop->opno;
expr_coll = saop->inputcollid;
index_relid = index->rel->relid;
opfamily = index->opfamily[indexcol];
idxcollation = index->indexcollations[indexcol];
/*
* We must have indexkey on the left and a pseudo-constant array argument.
*/
if (match_index_to_operand(leftop, indexcol, index) &&
!bms_is_member(index_relid, right_relids) &&
!contain_volatile_functions(rightop))
{
if (IndexCollMatchesExprColl(idxcollation, expr_coll) &&
op_in_opfamily(expr_op, opfamily))
{
IndexClause *iclause = makeNode(IndexClause);
iclause->rinfo = rinfo;
iclause->indexquals = list_make1(rinfo);
iclause->lossy = false;
iclause->indexcol = indexcol;
iclause->indexcols = NIL;
return iclause;
}
/*
* We do not currently ask support functions about ScalarArrayOpExprs,
* though in principle we could.
*/
}
return NULL;
}
/*
* match_rowcompare_to_indexcol()
* Handles the RowCompareExpr case for match_clause_to_indexcol(),
* which see for comments.
*
* In this routine we check whether the first column of the row comparison
* matches the target index column. This is sufficient to guarantee that some
* index condition can be constructed from the RowCompareExpr --- the rest
* is handled by expand_indexqual_rowcompare().
*/
static IndexClause *
match_rowcompare_to_indexcol(PlannerInfo *root,
RestrictInfo *rinfo,
int indexcol,
IndexOptInfo *index)
{
RowCompareExpr *clause = (RowCompareExpr *) rinfo->clause;
Index index_relid;
Oid opfamily;
Oid idxcollation;
Node *leftop,
*rightop;
bool var_on_left;
Oid expr_op;
Oid expr_coll;
/* Forget it if we're not dealing with a btree index */
if (index->relam != BTREE_AM_OID)
return NULL;
index_relid = index->rel->relid;
opfamily = index->opfamily[indexcol];
idxcollation = index->indexcollations[indexcol];
/*
* We could do the matching on the basis of insisting that the opfamily
* shown in the RowCompareExpr be the same as the index column's opfamily,
* but that could fail in the presence of reverse-sort opfamilies: it'd be
* a matter of chance whether RowCompareExpr had picked the forward or
* reverse-sort family. So look only at the operator, and match if it is
* a member of the index's opfamily (after commutation, if the indexkey is
* on the right). We'll worry later about whether any additional
* operators are matchable to the index.
*/
leftop = (Node *) linitial(clause->largs);
rightop = (Node *) linitial(clause->rargs);
expr_op = linitial_oid(clause->opnos);
expr_coll = linitial_oid(clause->inputcollids);
/* Collations must match, if relevant */
if (!IndexCollMatchesExprColl(idxcollation, expr_coll))
return NULL;
/*
* These syntactic tests are the same as in match_opclause_to_indexcol()
*/
if (match_index_to_operand(leftop, indexcol, index) &&
!bms_is_member(index_relid, pull_varnos(root, rightop)) &&
!contain_volatile_functions(rightop))
{
/* OK, indexkey is on left */
var_on_left = true;
}
else if (match_index_to_operand(rightop, indexcol, index) &&
!bms_is_member(index_relid, pull_varnos(root, leftop)) &&
!contain_volatile_functions(leftop))
{
/* indexkey is on right, so commute the operator */
expr_op = get_commutator(expr_op);
if (expr_op == InvalidOid)
return NULL;
var_on_left = false;
}
else
return NULL;
/* We're good if the operator is the right type of opfamily member */
switch (get_op_opfamily_strategy(expr_op, opfamily))
{
case BTLessStrategyNumber:
case BTLessEqualStrategyNumber:
case BTGreaterEqualStrategyNumber:
case BTGreaterStrategyNumber:
return expand_indexqual_rowcompare(root,
rinfo,
indexcol,
index,
expr_op,
var_on_left);
}
return NULL;
}
/*
* expand_indexqual_rowcompare --- expand a single indexqual condition
* that is a RowCompareExpr
*
* It's already known that the first column of the row comparison matches
* the specified column of the index. We can use additional columns of the
* row comparison as index qualifications, so long as they match the index
* in the "same direction", ie, the indexkeys are all on the same side of the
* clause and the operators are all the same-type members of the opfamilies.
*
* If all the columns of the RowCompareExpr match in this way, we just use it
* as-is, except for possibly commuting it to put the indexkeys on the left.
*
* Otherwise, we build a shortened RowCompareExpr (if more than one
* column matches) or a simple OpExpr (if the first-column match is all
* there is). In these cases the modified clause is always "<=" or ">="
* even when the original was "<" or ">" --- this is necessary to match all
* the rows that could match the original. (We are building a lossy version
* of the row comparison when we do this, so we set lossy = true.)
*
* Note: this is really just the last half of match_rowcompare_to_indexcol,
* but we split it out for comprehensibility.
*/
static IndexClause *
expand_indexqual_rowcompare(PlannerInfo *root,
RestrictInfo *rinfo,
int indexcol,
IndexOptInfo *index,
Oid expr_op,
bool var_on_left)
{
IndexClause *iclause = makeNode(IndexClause);
RowCompareExpr *clause = (RowCompareExpr *) rinfo->clause;
int op_strategy;
Oid op_lefttype;
Oid op_righttype;
int matching_cols;
List *expr_ops;
List *opfamilies;
List *lefttypes;
List *righttypes;
List *new_ops;
List *var_args;
List *non_var_args;
iclause->rinfo = rinfo;
iclause->indexcol = indexcol;
if (var_on_left)
{
var_args = clause->largs;
non_var_args = clause->rargs;
}
else
{
var_args = clause->rargs;
non_var_args = clause->largs;
}
get_op_opfamily_properties(expr_op, index->opfamily[indexcol], false,
&op_strategy,
&op_lefttype,
&op_righttype);
/* Initialize returned list of which index columns are used */
iclause->indexcols = list_make1_int(indexcol);
/* Build lists of ops, opfamilies and operator datatypes in case needed */
expr_ops = list_make1_oid(expr_op);
opfamilies = list_make1_oid(index->opfamily[indexcol]);
lefttypes = list_make1_oid(op_lefttype);
righttypes = list_make1_oid(op_righttype);
/*
* See how many of the remaining columns match some index column in the
* same way. As in match_clause_to_indexcol(), the "other" side of any
* potential index condition is OK as long as it doesn't use Vars from the
* indexed relation.
*/
matching_cols = 1;
while (matching_cols < list_length(var_args))
{
Node *varop = (Node *) list_nth(var_args, matching_cols);
Node *constop = (Node *) list_nth(non_var_args, matching_cols);
int i;
expr_op = list_nth_oid(clause->opnos, matching_cols);
if (!var_on_left)
{
/* indexkey is on right, so commute the operator */
expr_op = get_commutator(expr_op);
if (expr_op == InvalidOid)
break; /* operator is not usable */
}
if (bms_is_member(index->rel->relid, pull_varnos(root, constop)))
break; /* no good, Var on wrong side */
if (contain_volatile_functions(constop))
break; /* no good, volatile comparison value */
/*
* The Var side can match any key column of the index.
*/
for (i = 0; i < index->nkeycolumns; i++)
{
if (match_index_to_operand(varop, i, index) &&
get_op_opfamily_strategy(expr_op,
index->opfamily[i]) == op_strategy &&
IndexCollMatchesExprColl(index->indexcollations[i],
list_nth_oid(clause->inputcollids,
matching_cols)))
break;
}
if (i >= index->nkeycolumns)
break; /* no match found */
/* Add column number to returned list */
iclause->indexcols = lappend_int(iclause->indexcols, i);
/* Add operator info to lists */
get_op_opfamily_properties(expr_op, index->opfamily[i], false,
&op_strategy,
&op_lefttype,
&op_righttype);
expr_ops = lappend_oid(expr_ops, expr_op);
opfamilies = lappend_oid(opfamilies, index->opfamily[i]);
lefttypes = lappend_oid(lefttypes, op_lefttype);
righttypes = lappend_oid(righttypes, op_righttype);
/* This column matches, keep scanning */
matching_cols++;
}
/* Result is non-lossy if all columns are usable as index quals */
iclause->lossy = (matching_cols != list_length(clause->opnos));
/*
* We can use rinfo->clause as-is if we have var on left and it's all
* usable as index quals.
*/
if (var_on_left && !iclause->lossy)
iclause->indexquals = list_make1(rinfo);
else
{
/*
* We have to generate a modified rowcompare (possibly just one
* OpExpr). The painful part of this is changing < to <= or > to >=,
* so deal with that first.
*/
if (!iclause->lossy)
{
/* very easy, just use the commuted operators */
new_ops = expr_ops;
}
else if (op_strategy == BTLessEqualStrategyNumber ||
op_strategy == BTGreaterEqualStrategyNumber)
{
/* easy, just use the same (possibly commuted) operators */
new_ops = list_truncate(expr_ops, matching_cols);
}
else
{
ListCell *opfamilies_cell;
ListCell *lefttypes_cell;
ListCell *righttypes_cell;
if (op_strategy == BTLessStrategyNumber)
op_strategy = BTLessEqualStrategyNumber;
else if (op_strategy == BTGreaterStrategyNumber)
op_strategy = BTGreaterEqualStrategyNumber;
else
elog(ERROR, "unexpected strategy number %d", op_strategy);
new_ops = NIL;
forthree(opfamilies_cell, opfamilies,
lefttypes_cell, lefttypes,
righttypes_cell, righttypes)
{
Oid opfam = lfirst_oid(opfamilies_cell);
Oid lefttype = lfirst_oid(lefttypes_cell);
Oid righttype = lfirst_oid(righttypes_cell);
expr_op = get_opfamily_member(opfam, lefttype, righttype,
op_strategy);
if (!OidIsValid(expr_op)) /* should not happen */
elog(ERROR, "missing operator %d(%u,%u) in opfamily %u",
op_strategy, lefttype, righttype, opfam);
new_ops = lappend_oid(new_ops, expr_op);
}
}
/* If we have more than one matching col, create a subset rowcompare */
if (matching_cols > 1)
{
RowCompareExpr *rc = makeNode(RowCompareExpr);
rc->rctype = (RowCompareType) op_strategy;
rc->opnos = new_ops;
rc->opfamilies = list_copy_head(clause->opfamilies,
matching_cols);
rc->inputcollids = list_copy_head(clause->inputcollids,
matching_cols);
rc->largs = list_copy_head(var_args, matching_cols);
rc->rargs = list_copy_head(non_var_args, matching_cols);
iclause->indexquals = list_make1(make_simple_restrictinfo(root,
(Expr *) rc));
}
else
{
Expr *op;
/* We don't report an index column list in this case */
iclause->indexcols = NIL;
op = make_opclause(linitial_oid(new_ops), BOOLOID, false,
copyObject(linitial(var_args)),
copyObject(linitial(non_var_args)),
InvalidOid,
linitial_oid(clause->inputcollids));
iclause->indexquals = list_make1(make_simple_restrictinfo(root, op));
}
}
return iclause;
}
/****************************************************************************
* ---- ROUTINES TO CHECK ORDERING OPERATORS ----
****************************************************************************/
/*
* match_pathkeys_to_index
* Test whether an index can produce output ordered according to the
* given pathkeys using "ordering operators".
*
* If it can, return a list of suitable ORDER BY expressions, each of the form
* "indexedcol operator pseudoconstant", along with an integer list of the
* index column numbers (zero based) that each clause would be used with.
* NIL lists are returned if the ordering is not achievable this way.
*
* On success, the result list is ordered by pathkeys, and in fact is
* one-to-one with the requested pathkeys.
*/
static void
match_pathkeys_to_index(IndexOptInfo *index, List *pathkeys,
List **orderby_clauses_p,
List **clause_columns_p)
{
List *orderby_clauses = NIL;
List *clause_columns = NIL;
ListCell *lc1;
*orderby_clauses_p = NIL; /* set default results */
*clause_columns_p = NIL;
/* Only indexes with the amcanorderbyop property are interesting here */
if (!index->amcanorderbyop)
return;
foreach(lc1, pathkeys)
{
PathKey *pathkey = (PathKey *) lfirst(lc1);
bool found = false;
ListCell *lc2;
/*
* Note: for any failure to match, we just return NIL immediately.
* There is no value in matching just some of the pathkeys.
*/
/* Pathkey must request default sort order for the target opfamily */
if (pathkey->pk_strategy != BTLessStrategyNumber ||
pathkey->pk_nulls_first)
return;
/* If eclass is volatile, no hope of using an indexscan */
if (pathkey->pk_eclass->ec_has_volatile)
return;
/*
* Try to match eclass member expression(s) to index. Note that child
* EC members are considered, but only when they belong to the target
* relation. (Unlike regular members, the same expression could be a
* child member of more than one EC. Therefore, the same index could
* be considered to match more than one pathkey list, which is OK
* here. See also get_eclass_for_sort_expr.)
*/
foreach(lc2, pathkey->pk_eclass->ec_members)
{
EquivalenceMember *member = (EquivalenceMember *) lfirst(lc2);
int indexcol;
/* No possibility of match if it references other relations */
if (!bms_equal(member->em_relids, index->rel->relids))
continue;
/*
* We allow any column of the index to match each pathkey; they
* don't have to match left-to-right as you might expect. This is
* correct for GiST, and it doesn't matter for SP-GiST because
* that doesn't handle multiple columns anyway, and no other
* existing AMs support amcanorderbyop. We might need different
* logic in future for other implementations.
*/
for (indexcol = 0; indexcol < index->nkeycolumns; indexcol++)
{
Expr *expr;
expr = match_clause_to_ordering_op(index,
indexcol,
member->em_expr,
pathkey->pk_opfamily);
if (expr)
{
orderby_clauses = lappend(orderby_clauses, expr);
clause_columns = lappend_int(clause_columns, indexcol);
found = true;
break;
}
}
if (found) /* don't want to look at remaining members */
break;
}
if (!found) /* fail if no match for this pathkey */
return;
}
*orderby_clauses_p = orderby_clauses; /* success! */
*clause_columns_p = clause_columns;
}
/*
* match_clause_to_ordering_op
* Determines whether an ordering operator expression matches an
* index column.
*
* This is similar to, but simpler than, match_clause_to_indexcol.
* We only care about simple OpExpr cases. The input is a bare
* expression that is being ordered by, which must be of the form
* (indexkey op const) or (const op indexkey) where op is an ordering
* operator for the column's opfamily.
*
* 'index' is the index of interest.
* 'indexcol' is a column number of 'index' (counting from 0).
* 'clause' is the ordering expression to be tested.
* 'pk_opfamily' is the btree opfamily describing the required sort order.
*
* Note that we currently do not consider the collation of the ordering
* operator's result. In practical cases the result type will be numeric
* and thus have no collation, and it's not very clear what to match to
* if it did have a collation. The index's collation should match the
* ordering operator's input collation, not its result.
*
* If successful, return 'clause' as-is if the indexkey is on the left,
* otherwise a commuted copy of 'clause'. If no match, return NULL.
*/
static Expr *
match_clause_to_ordering_op(IndexOptInfo *index,
int indexcol,
Expr *clause,
Oid pk_opfamily)
{
Oid opfamily;
Oid idxcollation;
Node *leftop,
*rightop;
Oid expr_op;
Oid expr_coll;
Oid sortfamily;
bool commuted;
Assert(indexcol < index->nkeycolumns);
opfamily = index->opfamily[indexcol];
idxcollation = index->indexcollations[indexcol];
/*
* Clause must be a binary opclause.
*/
if (!is_opclause(clause))
return NULL;
leftop = get_leftop(clause);
rightop = get_rightop(clause);
if (!leftop || !rightop)
return NULL;
expr_op = ((OpExpr *) clause)->opno;
expr_coll = ((OpExpr *) clause)->inputcollid;
/*
* We can forget the whole thing right away if wrong collation.
*/
if (!IndexCollMatchesExprColl(idxcollation, expr_coll))
return NULL;
/*
* Check for clauses of the form: (indexkey operator constant) or
* (constant operator indexkey).
*/
if (match_index_to_operand(leftop, indexcol, index) &&
!contain_var_clause(rightop) &&
!contain_volatile_functions(rightop))
{
commuted = false;
}
else if (match_index_to_operand(rightop, indexcol, index) &&
!contain_var_clause(leftop) &&
!contain_volatile_functions(leftop))
{
/* Might match, but we need a commuted operator */
expr_op = get_commutator(expr_op);
if (expr_op == InvalidOid)
return NULL;
commuted = true;
}
else
return NULL;
/*
* Is the (commuted) operator an ordering operator for the opfamily? And
* if so, does it yield the right sorting semantics?
*/
sortfamily = get_op_opfamily_sortfamily(expr_op, opfamily);
if (sortfamily != pk_opfamily)
return NULL;
/* We have a match. Return clause or a commuted version thereof. */
if (commuted)
{
OpExpr *newclause = makeNode(OpExpr);
/* flat-copy all the fields of clause */
memcpy(newclause, clause, sizeof(OpExpr));
/* commute it */
newclause->opno = expr_op;
newclause->opfuncid = InvalidOid;
newclause->args = list_make2(rightop, leftop);
clause = (Expr *) newclause;
}
return clause;
}
/****************************************************************************
* ---- ROUTINES TO DO PARTIAL INDEX PREDICATE TESTS ----
****************************************************************************/
/*
* check_index_predicates
* Set the predicate-derived IndexOptInfo fields for each index
* of the specified relation.
*
* predOK is set true if the index is partial and its predicate is satisfied
* for this query, ie the query's WHERE clauses imply the predicate.
*
* indrestrictinfo is set to the relation's baserestrictinfo list less any
* conditions that are implied by the index's predicate. (Obviously, for a
* non-partial index, this is the same as baserestrictinfo.) Such conditions
* can be dropped from the plan when using the index, in certain cases.
*
* At one time it was possible for this to get re-run after adding more
* restrictions to the rel, thus possibly letting us prove more indexes OK.
* That doesn't happen any more (at least not in the core code's usage),
* but this code still supports it in case extensions want to mess with the
* baserestrictinfo list. We assume that adding more restrictions can't make
* an index not predOK. We must recompute indrestrictinfo each time, though,
* to make sure any newly-added restrictions get into it if needed.
*/
void
check_index_predicates(PlannerInfo *root, RelOptInfo *rel)
{
List *clauselist;
bool have_partial;
bool is_target_rel;
Relids otherrels;
ListCell *lc;
/* Indexes are available only on base or "other" member relations. */
Assert(IS_SIMPLE_REL(rel));
/*
* Initialize the indrestrictinfo lists to be identical to
* baserestrictinfo, and check whether there are any partial indexes. If
* not, this is all we need to do.
*/
have_partial = false;
foreach(lc, rel->indexlist)
{
IndexOptInfo *index = (IndexOptInfo *) lfirst(lc);
index->indrestrictinfo = rel->baserestrictinfo;
if (index->indpred)
have_partial = true;
}
if (!have_partial)
return;
/*
* Construct a list of clauses that we can assume true for the purpose of
* proving the index(es) usable. Restriction clauses for the rel are
* always usable, and so are any join clauses that are "movable to" this
* rel. Also, we can consider any EC-derivable join clauses (which must
* be "movable to" this rel, by definition).
*/
clauselist = list_copy(rel->baserestrictinfo);
/* Scan the rel's join clauses */
foreach(lc, rel->joininfo)
{
RestrictInfo *rinfo = (RestrictInfo *) lfirst(lc);
/* Check if clause can be moved to this rel */
if (!join_clause_is_movable_to(rinfo, rel))
continue;
clauselist = lappend(clauselist, rinfo);
}
/*
* Add on any equivalence-derivable join clauses. Computing the correct
* relid sets for generate_join_implied_equalities is slightly tricky
* because the rel could be a child rel rather than a true baserel, and in
* that case we must subtract its parents' relid(s) from all_query_rels.
* Additionally, we mustn't consider clauses that are only computable
* after outer joins that can null the rel.
*/
if (rel->reloptkind == RELOPT_OTHER_MEMBER_REL)
otherrels = bms_difference(root->all_query_rels,
find_childrel_parents(root, rel));
else
otherrels = bms_difference(root->all_query_rels, rel->relids);
otherrels = bms_del_members(otherrels, rel->nulling_relids);
if (!bms_is_empty(otherrels))
clauselist =
list_concat(clauselist,
generate_join_implied_equalities(root,
bms_union(rel->relids,
otherrels),
otherrels,
rel,
NULL));
/*
* Normally we remove quals that are implied by a partial index's
* predicate from indrestrictinfo, indicating that they need not be
* checked explicitly by an indexscan plan using this index. However, if
* the rel is a target relation of UPDATE/DELETE/MERGE/SELECT FOR UPDATE,
* we cannot remove such quals from the plan, because they need to be in
* the plan so that they will be properly rechecked by EvalPlanQual
* testing. Some day we might want to remove such quals from the main
* plan anyway and pass them through to EvalPlanQual via a side channel;
* but for now, we just don't remove implied quals at all for target
* relations.
*/
is_target_rel = (bms_is_member(rel->relid, root->all_result_relids) ||
get_plan_rowmark(root->rowMarks, rel->relid) != NULL);
/*
* Now try to prove each index predicate true, and compute the
* indrestrictinfo lists for partial indexes. Note that we compute the
* indrestrictinfo list even for non-predOK indexes; this might seem
* wasteful, but we may be able to use such indexes in OR clauses, cf
* generate_bitmap_or_paths().
*/
foreach(lc, rel->indexlist)
{
IndexOptInfo *index = (IndexOptInfo *) lfirst(lc);
ListCell *lcr;
if (index->indpred == NIL)
continue; /* ignore non-partial indexes here */
if (!index->predOK) /* don't repeat work if already proven OK */
index->predOK = predicate_implied_by(index->indpred, clauselist,
false);
/* If rel is an update target, leave indrestrictinfo as set above */
if (is_target_rel)
continue;
/* Else compute indrestrictinfo as the non-implied quals */
index->indrestrictinfo = NIL;
foreach(lcr, rel->baserestrictinfo)
{
RestrictInfo *rinfo = (RestrictInfo *) lfirst(lcr);
/* predicate_implied_by() assumes first arg is immutable */
if (contain_mutable_functions((Node *) rinfo->clause) ||
!predicate_implied_by(list_make1(rinfo->clause),
index->indpred, false))
index->indrestrictinfo = lappend(index->indrestrictinfo, rinfo);
}
}
}
/****************************************************************************
* ---- ROUTINES TO CHECK EXTERNALLY-VISIBLE CONDITIONS ----
****************************************************************************/
/*
* ec_member_matches_indexcol
* Test whether an EquivalenceClass member matches an index column.
*
* This is a callback for use by generate_implied_equalities_for_column.
*/
static bool
ec_member_matches_indexcol(PlannerInfo *root, RelOptInfo *rel,
EquivalenceClass *ec, EquivalenceMember *em,
void *arg)
{
IndexOptInfo *index = ((ec_member_matches_arg *) arg)->index;
int indexcol = ((ec_member_matches_arg *) arg)->indexcol;
Oid curFamily;
Oid curCollation;
Assert(indexcol < index->nkeycolumns);
curFamily = index->opfamily[indexcol];
curCollation = index->indexcollations[indexcol];
/*
* If it's a btree index, we can reject it if its opfamily isn't
* compatible with the EC, since no clause generated from the EC could be
* used with the index. For non-btree indexes, we can't easily tell
* whether clauses generated from the EC could be used with the index, so
* don't check the opfamily. This might mean we return "true" for a
* useless EC, so we have to recheck the results of
* generate_implied_equalities_for_column; see
* match_eclass_clauses_to_index.
*/
if (index->relam == BTREE_AM_OID &&
!list_member_oid(ec->ec_opfamilies, curFamily))
return false;
/* We insist on collation match for all index types, though */
if (!IndexCollMatchesExprColl(curCollation, ec->ec_collation))
return false;
return match_index_to_operand((Node *) em->em_expr, indexcol, index);
}
/*
* relation_has_unique_index_for
* Determine whether the relation provably has at most one row satisfying
* a set of equality conditions, because the conditions constrain all
* columns of some unique index.
*
* The conditions can be represented in either or both of two ways:
* 1. A list of RestrictInfo nodes, where the caller has already determined
* that each condition is a mergejoinable equality with an expression in
* this relation on one side, and an expression not involving this relation
* on the other. The transient outer_is_left flag is used to identify which
* side we should look at: left side if outer_is_left is false, right side
* if it is true.
* 2. A list of expressions in this relation, and a corresponding list of
* equality operators. The caller must have already checked that the operators
* represent equality. (Note: the operators could be cross-type; the
* expressions should correspond to their RHS inputs.)
*
* The caller need only supply equality conditions arising from joins;
* this routine automatically adds in any usable baserestrictinfo clauses.
* (Note that the passed-in restrictlist will be destructively modified!)
*/
bool
relation_has_unique_index_for(PlannerInfo *root, RelOptInfo *rel,
List *restrictlist,
List *exprlist, List *oprlist)
{
ListCell *ic;
Assert(list_length(exprlist) == list_length(oprlist));
/* Short-circuit if no indexes... */
if (rel->indexlist == NIL)
return false;
/*
* Examine the rel's restriction clauses for usable var = const clauses
* that we can add to the restrictlist.
*/
foreach(ic, rel->baserestrictinfo)
{
RestrictInfo *restrictinfo = (RestrictInfo *) lfirst(ic);
/*
* Note: can_join won't be set for a restriction clause, but
* mergeopfamilies will be if it has a mergejoinable operator and
* doesn't contain volatile functions.
*/
if (restrictinfo->mergeopfamilies == NIL)
continue; /* not mergejoinable */
/*
* The clause certainly doesn't refer to anything but the given rel.
* If either side is pseudoconstant then we can use it.
*/
if (bms_is_empty(restrictinfo->left_relids))
{
/* righthand side is inner */
restrictinfo->outer_is_left = true;
}
else if (bms_is_empty(restrictinfo->right_relids))
{
/* lefthand side is inner */
restrictinfo->outer_is_left = false;
}
else
continue;
/* OK, add to list */
restrictlist = lappend(restrictlist, restrictinfo);
}
/* Short-circuit the easy case */
if (restrictlist == NIL && exprlist == NIL)
return false;
/* Examine each index of the relation ... */
foreach(ic, rel->indexlist)
{
IndexOptInfo *ind = (IndexOptInfo *) lfirst(ic);
int c;
/*
* If the index is not unique, or not immediately enforced, or if it's
* a partial index that doesn't match the query, it's useless here.
*/
if (!ind->unique || !ind->immediate ||
(ind->indpred != NIL && !ind->predOK))
continue;
/*
* Try to find each index column in the lists of conditions. This is
* O(N^2) or worse, but we expect all the lists to be short.
*/
for (c = 0; c < ind->nkeycolumns; c++)
{
bool matched = false;
ListCell *lc;
ListCell *lc2;
foreach(lc, restrictlist)
{
RestrictInfo *rinfo = (RestrictInfo *) lfirst(lc);
Node *rexpr;
/*
* The condition's equality operator must be a member of the
* index opfamily, else it is not asserting the right kind of
* equality behavior for this index. We check this first
* since it's probably cheaper than match_index_to_operand().
*/
if (!list_member_oid(rinfo->mergeopfamilies, ind->opfamily[c]))
continue;
/*
* XXX at some point we may need to check collations here too.
* For the moment we assume all collations reduce to the same
* notion of equality.
*/
/* OK, see if the condition operand matches the index key */
if (rinfo->outer_is_left)
rexpr = get_rightop(rinfo->clause);
else
rexpr = get_leftop(rinfo->clause);
if (match_index_to_operand(rexpr, c, ind))
{
matched = true; /* column is unique */
break;
}
}
if (matched)
continue;
forboth(lc, exprlist, lc2, oprlist)
{
Node *expr = (Node *) lfirst(lc);
Oid opr = lfirst_oid(lc2);
/* See if the expression matches the index key */
if (!match_index_to_operand(expr, c, ind))
continue;
/*
* The equality operator must be a member of the index
* opfamily, else it is not asserting the right kind of
* equality behavior for this index. We assume the caller
* determined it is an equality operator, so we don't need to
* check any more tightly than this.
*/
if (!op_in_opfamily(opr, ind->opfamily[c]))
continue;
/*
* XXX at some point we may need to check collations here too.
* For the moment we assume all collations reduce to the same
* notion of equality.
*/
matched = true; /* column is unique */
break;
}
if (!matched)
break; /* no match; this index doesn't help us */
}
/* Matched all key columns of this index? */
if (c == ind->nkeycolumns)
return true;
}
return false;
}
/*
* indexcol_is_bool_constant_for_query
*
* If an index column is constrained to have a constant value by the query's
* WHERE conditions, then it's irrelevant for sort-order considerations.
* Usually that means we have a restriction clause WHERE indexcol = constant,
* which gets turned into an EquivalenceClass containing a constant, which
* is recognized as redundant by build_index_pathkeys(). But if the index
* column is a boolean variable (or expression), then we are not going to
* see WHERE indexcol = constant, because expression preprocessing will have
* simplified that to "WHERE indexcol" or "WHERE NOT indexcol". So we are not
* going to have a matching EquivalenceClass (unless the query also contains
* "ORDER BY indexcol"). To allow such cases to work the same as they would
* for non-boolean values, this function is provided to detect whether the
* specified index column matches a boolean restriction clause.
*/
bool
indexcol_is_bool_constant_for_query(PlannerInfo *root,
IndexOptInfo *index,
int indexcol)
{
ListCell *lc;
/* If the index isn't boolean, we can't possibly get a match */
if (!IsBooleanOpfamily(index->opfamily[indexcol]))
return false;
/* Check each restriction clause for the index's rel */
foreach(lc, index->rel->baserestrictinfo)
{
RestrictInfo *rinfo = (RestrictInfo *) lfirst(lc);
/*
* As in match_clause_to_indexcol, never match pseudoconstants to
* indexes. (It might be semantically okay to do so here, but the
* odds of getting a match are negligible, so don't waste the cycles.)
*/
if (rinfo->pseudoconstant)
continue;
/* See if we can match the clause's expression to the index column */
if (match_boolean_index_clause(root, rinfo, indexcol, index))
return true;
}
return false;
}
/****************************************************************************
* ---- ROUTINES TO CHECK OPERANDS ----
****************************************************************************/
/*
* match_index_to_operand()
* Generalized test for a match between an index's key
* and the operand on one side of a restriction or join clause.
*
* operand: the nodetree to be compared to the index
* indexcol: the column number of the index (counting from 0)
* index: the index of interest
*
* Note that we aren't interested in collations here; the caller must check
* for a collation match, if it's dealing with an operator where that matters.
*
* This is exported for use in selfuncs.c.
*/
bool
match_index_to_operand(Node *operand,
int indexcol,
IndexOptInfo *index)
{
int indkey;
/*
* Ignore any RelabelType node above the operand. This is needed to be
* able to apply indexscanning in binary-compatible-operator cases. Note:
* we can assume there is at most one RelabelType node;
* eval_const_expressions() will have simplified if more than one.
*/
if (operand && IsA(operand, RelabelType))
operand = (Node *) ((RelabelType *) operand)->arg;
indkey = index->indexkeys[indexcol];
if (indkey != 0)
{
/*
* Simple index column; operand must be a matching Var.
*/
if (operand && IsA(operand, Var) &&
index->rel->relid == ((Var *) operand)->varno &&
indkey == ((Var *) operand)->varattno &&
((Var *) operand)->varnullingrels == NULL)
return true;
}
else
{
/*
* Index expression; find the correct expression. (This search could
* be avoided, at the cost of complicating all the callers of this
* routine; doesn't seem worth it.)
*/
ListCell *indexpr_item;
int i;
Node *indexkey;
indexpr_item = list_head(index->indexprs);
for (i = 0; i < indexcol; i++)
{
if (index->indexkeys[i] == 0)
{
if (indexpr_item == NULL)
elog(ERROR, "wrong number of index expressions");
indexpr_item = lnext(index->indexprs, indexpr_item);
}
}
if (indexpr_item == NULL)
elog(ERROR, "wrong number of index expressions");
indexkey = (Node *) lfirst(indexpr_item);
/*
* Does it match the operand? Again, strip any relabeling.
*/
if (indexkey && IsA(indexkey, RelabelType))
indexkey = (Node *) ((RelabelType *) indexkey)->arg;
if (equal(indexkey, operand))
return true;
}
return false;
}
/*
* is_pseudo_constant_for_index()
* Test whether the given expression can be used as an indexscan
* comparison value.
*
* An indexscan comparison value must not contain any volatile functions,
* and it can't contain any Vars of the index's own table. Vars of
* other tables are okay, though; in that case we'd be producing an
* indexqual usable in a parameterized indexscan. This is, therefore,
* a weaker condition than is_pseudo_constant_clause().
*
* This function is exported for use by planner support functions,
* which will have available the IndexOptInfo, but not any RestrictInfo
* infrastructure. It is making the same test made by functions above
* such as match_opclause_to_indexcol(), but those rely where possible
* on RestrictInfo information about variable membership.
*
* expr: the nodetree to be checked
* index: the index of interest
*/
bool
is_pseudo_constant_for_index(PlannerInfo *root, Node *expr, IndexOptInfo *index)
{
/* pull_varnos is cheaper than volatility check, so do that first */
if (bms_is_member(index->rel->relid, pull_varnos(root, expr)))
return false; /* no good, contains Var of table */
if (contain_volatile_functions(expr))
return false; /* no good, volatile comparison value */
return true;
}
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