Be smart about outer-join qualifications that mention only one side of

the join, per recent discussion on pgsql-sql.  Not clear that this will
come up often in real queries, but it's not any more expensive to do it
right, so we may as well do it right.
This commit is contained in:
Tom Lane 2003-03-02 23:46:34 +00:00
parent a1dbe521bc
commit 30a695d356

View File

@ -8,7 +8,7 @@
*
*
* IDENTIFICATION
* $Header: /cvsroot/pgsql/src/backend/optimizer/plan/initsplan.c,v 1.84 2003/02/08 20:20:54 tgl Exp $
* $Header: /cvsroot/pgsql/src/backend/optimizer/plan/initsplan.c,v 1.85 2003/03/02 23:46:34 tgl Exp $
*
*-------------------------------------------------------------------------
*/
@ -37,8 +37,8 @@ static void mark_baserels_for_outer_join(Query *root, Relids rels,
Relids outerrels);
static void distribute_qual_to_rels(Query *root, Node *clause,
bool ispusheddown,
bool isouterjoin,
bool isdeduced,
Relids outerjoin_nonnullable,
Relids qualscope);
static void add_vars_to_targetlist(Query *root, List *vars);
static bool qual_is_redundant(Query *root, RestrictInfo *restrictinfo,
@ -209,48 +209,53 @@ distribute_quals_to_rels(Query *root, Node *jtnode)
*/
foreach(qual, (List *) f->quals)
distribute_qual_to_rels(root, (Node *) lfirst(qual),
true, false, false, result);
true, false, NULL, result);
}
else if (IsA(jtnode, JoinExpr))
{
JoinExpr *j = (JoinExpr *) jtnode;
Relids leftids,
rightids;
bool isouterjoin;
rightids,
nonnullable_rels,
nullable_rels;
List *qual;
/*
* Order of operations here is subtle and critical. First we
* recurse to handle sub-JOINs. Their join quals will be placed
* without regard for whether this level is an outer join, which
* is correct. Then, if we are an outer join, we mark baserels
* contained within the nullable side(s) with our own rel set;
* this will restrict placement of subsequent quals using those
* rels, including our own quals and quals above us in the join
* tree. Finally we place our own join quals.
* is correct. Then we place our own join quals, which are restricted
* by lower outer joins in any case, and are forced to this level if
* this is an outer join and they mention the outer side. Finally, if
* this is an outer join, we mark baserels contained within the inner
* side(s) with our own rel set; this will prevent quals above us in
* the join tree that use those rels from being pushed down below this
* level. (It's okay for upper quals to be pushed down to the outer
* side, however.)
*/
leftids = distribute_quals_to_rels(root, j->larg);
rightids = distribute_quals_to_rels(root, j->rarg);
result = bms_union(leftids, rightids);
isouterjoin = false;
nonnullable_rels = nullable_rels = NULL;
switch (j->jointype)
{
case JOIN_INNER:
/* Inner join adds no restrictions for quals */
break;
case JOIN_LEFT:
mark_baserels_for_outer_join(root, rightids, result);
isouterjoin = true;
nonnullable_rels = leftids;
nullable_rels = rightids;
break;
case JOIN_FULL:
mark_baserels_for_outer_join(root, result, result);
isouterjoin = true;
/* each side is both outer and inner */
nonnullable_rels = result;
nullable_rels = result;
break;
case JOIN_RIGHT:
mark_baserels_for_outer_join(root, leftids, result);
isouterjoin = true;
nonnullable_rels = rightids;
nullable_rels = leftids;
break;
case JOIN_UNION:
@ -269,7 +274,11 @@ distribute_quals_to_rels(Query *root, Node *jtnode)
foreach(qual, (List *) j->quals)
distribute_qual_to_rels(root, (Node *) lfirst(qual),
false, isouterjoin, false, result);
false, false,
nonnullable_rels, result);
if (nullable_rels != NULL)
mark_baserels_for_outer_join(root, nullable_rels, result);
}
else
elog(ERROR, "distribute_quals_to_rels: unexpected node type %d",
@ -324,14 +333,16 @@ mark_baserels_for_outer_join(Query *root, Relids rels, Relids outerrels)
* (depending on whether the clause is a join) of each base relation
* mentioned in the clause. A RestrictInfo node is created and added to
* the appropriate list for each rel. Also, if the clause uses a
* mergejoinable operator and is not an outer-join qual, enter the left-
* and right-side expressions into the query's lists of equijoined vars.
* mergejoinable operator and is not delayed by outer-join rules, enter
* the left- and right-side expressions into the query's lists of
* equijoined vars.
*
* 'clause': the qual clause to be distributed
* 'ispusheddown': if TRUE, force the clause to be marked 'ispusheddown'
* (this indicates the clause came from a FromExpr, not a JoinExpr)
* 'isouterjoin': TRUE if the qual came from an OUTER JOIN's ON-clause
* 'isdeduced': TRUE if the qual came from implied-equality deduction
* 'outerjoin_nonnullable': NULL if not an outer-join qual, else the set of
* baserels appearing on the outer (nonnullable) side of the join
* 'qualscope': set of baserels the qual's syntactic scope covers
*
* 'qualscope' identifies what level of JOIN the qual came from. For a top
@ -341,8 +352,8 @@ mark_baserels_for_outer_join(Query *root, Relids rels, Relids outerrels)
static void
distribute_qual_to_rels(Query *root, Node *clause,
bool ispusheddown,
bool isouterjoin,
bool isdeduced,
Relids outerjoin_nonnullable,
Relids qualscope)
{
RestrictInfo *restrictinfo = makeNode(RestrictInfo);
@ -392,63 +403,80 @@ distribute_qual_to_rels(Query *root, Node *clause,
relids = qualscope;
/*
* For an outer-join qual, pretend that the clause references all rels
* appearing within its syntactic scope, even if it really doesn't.
* This ensures that the clause will be evaluated exactly at the level
* of joining corresponding to the outer join.
*
* For a non-outer-join qual, we can evaluate the qual as soon as (1) we
* have all the rels it mentions, and (2) we are at or above any outer
* joins that can null any of these rels and are below the syntactic
* location of the given qual. To enforce the latter, scan the base
* rels listed in relids, and merge their outer-join sets into the
* clause's own reference list. At the time we are called, the
* outerjoinset of each baserel will show exactly those outer
* joins that are below the qual in the join tree.
*
* If the qual came from implied-equality deduction, we can evaluate the
* qual at its natural semantic level.
*
* Check to see if clause application must be delayed by outer-join
* considerations.
*/
if (isdeduced)
{
/*
* If the qual came from implied-equality deduction, we can evaluate
* the qual at its natural semantic level. It is not affected by
* any outer-join rules (else we'd not have decided the vars were
* equal).
*/
Assert(bms_equal(relids, qualscope));
can_be_equijoin = true;
}
else if (isouterjoin)
else if (bms_overlap(relids, outerjoin_nonnullable))
{
/*
* The qual is attached to an outer join and mentions (some of the)
* rels on the nonnullable side. Force the qual to be evaluated
* exactly at the level of joining corresponding to the outer join.
* We cannot let it get pushed down into the nonnullable side, since
* then we'd produce no output rows, rather than the intended single
* null-extended row, for any nonnullable-side rows failing the qual.
*
* Note: an outer-join qual that mentions only nullable-side rels can
* be pushed down into the nullable side without changing the join
* result, so we treat it the same as an ordinary inner-join qual.
*/
relids = qualscope;
can_be_equijoin = false;
}
else
{
/* copy to ensure we don't change caller's qualscope set */
Relids newrelids = bms_copy(relids);
/*
* For a non-outer-join qual, we can evaluate the qual as soon as
* (1) we have all the rels it mentions, and (2) we are at or above
* any outer joins that can null any of these rels and are below the
* syntactic location of the given qual. To enforce the latter, scan
* the base rels listed in relids, and merge their outer-join sets
* into the clause's own reference list. At the time we are called,
* the outerjoinset of each baserel will show exactly those outer
* joins that are below the qual in the join tree.
*/
Relids addrelids = NULL;
Relids tmprelids;
int relno;
can_be_equijoin = true;
tmprelids = bms_copy(relids);
while ((relno = bms_first_member(tmprelids)) >= 0)
{
RelOptInfo *rel = find_base_rel(root, relno);
if (!bms_is_subset(rel->outerjoinset, relids))
{
newrelids = bms_add_members(newrelids, rel->outerjoinset);
if (rel->outerjoinset != NULL)
addrelids = bms_add_members(addrelids, rel->outerjoinset);
}
bms_free(tmprelids);
if (bms_is_subset(addrelids, relids))
{
/* Qual is not affected by any outer-join restriction */
can_be_equijoin = true;
}
else
{
relids = bms_union(relids, addrelids);
/* Should still be a subset of current scope ... */
Assert(bms_is_subset(relids, qualscope));
/*
* Because application of the qual will be delayed by
* outer join, we mustn't assume its vars are equal
* everywhere.
* Because application of the qual will be delayed by outer join,
* we mustn't assume its vars are equal everywhere.
*/
can_be_equijoin = false;
}
}
bms_free(tmprelids);
relids = newrelids;
/* Should still be a subset of current scope ... */
Assert(bms_is_subset(relids, qualscope));
bms_free(addrelids);
}
/*
@ -725,8 +753,7 @@ process_implied_equality(Query *root,
* taken for an original JOIN/ON clause.
*/
distribute_qual_to_rels(root, (Node *) clause,
true, false, true,
relids);
true, true, NULL, relids);
}
/*