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postgres/src/backend/optimizer/prep/prepjointree.c
Alvaro Herrera 055fb8d33d Add GUC enable_partition_pruning 
This controls both plan-time and execution-time new-style partition
pruning.  While finer-grain control is possible (maybe using an enum GUC
instead of boolean), there doesn't seem to be much need for that.

This new parameter controls partition pruning for all queries:
trivially, SELECT queries that affect partitioned tables are naturally
under its control since they are using the new technology.  However,
while UPDATE/DELETE queries do not use the new code, we make the new GUC
control their behavior also (stealing control from
constraint_exclusion), because it is more natural, and it leads to a
more natural transition to the future in which those queries will also
use the new pruning code.

Constraint exclusion still controls pruning for regular inheritance
situations (those not involving partitioned tables).

Author: David Rowley
Review: Amit Langote, Ashutosh Bapat, Justin Pryzby, David G. Johnston
Discussion: https://postgr.es/m/CAKJS1f_0HwsxJG9m+nzU+CizxSdGtfe6iF_ykPYBiYft302DCw@mail.gmail.com
2018-04-23 17:57:43 -03:00

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/*-------------------------------------------------------------------------
*
* prepjointree.c
* Planner preprocessing for subqueries and join tree manipulation.
*
* NOTE: the intended sequence for invoking these operations is
* pull_up_sublinks
* inline_set_returning_functions
* pull_up_subqueries
* flatten_simple_union_all
* do expression preprocessing (including flattening JOIN alias vars)
* reduce_outer_joins
*
*
* Portions Copyright (c) 1996-2018, PostgreSQL Global Development Group
* Portions Copyright (c) 1994, Regents of the University of California
*
*
* IDENTIFICATION
* src/backend/optimizer/prep/prepjointree.c
*
*-------------------------------------------------------------------------
*/
#include "postgres.h"
#include "catalog/pg_type.h"
#include "nodes/makefuncs.h"
#include "nodes/nodeFuncs.h"
#include "optimizer/clauses.h"
#include "optimizer/placeholder.h"
#include "optimizer/prep.h"
#include "optimizer/subselect.h"
#include "optimizer/tlist.h"
#include "optimizer/var.h"
#include "parser/parse_relation.h"
#include "parser/parsetree.h"
#include "rewrite/rewriteManip.h"
typedef struct pullup_replace_vars_context
{
PlannerInfo *root;
List *targetlist; /* tlist of subquery being pulled up */
RangeTblEntry *target_rte; /* RTE of subquery */
Relids relids; /* relids within subquery, as numbered after
* pullup (set only if target_rte->lateral) */
bool *outer_hasSubLinks; /* -> outer query's hasSubLinks */
int varno; /* varno of subquery */
bool need_phvs; /* do we need PlaceHolderVars? */
bool wrap_non_vars; /* do we need 'em on *all* non-Vars? */
Node **rv_cache; /* cache for results with PHVs */
} pullup_replace_vars_context;
typedef struct reduce_outer_joins_state
{
Relids relids; /* base relids within this subtree */
bool contains_outer; /* does subtree contain outer join(s)? */
List *sub_states; /* List of states for subtree components */
} reduce_outer_joins_state;
static Node *pull_up_sublinks_jointree_recurse(PlannerInfo *root, Node *jtnode,
Relids *relids);
static Node *pull_up_sublinks_qual_recurse(PlannerInfo *root, Node *node,
Node **jtlink1, Relids available_rels1,
Node **jtlink2, Relids available_rels2);
static Node *pull_up_subqueries_recurse(PlannerInfo *root, Node *jtnode,
JoinExpr *lowest_outer_join,
JoinExpr *lowest_nulling_outer_join,
AppendRelInfo *containing_appendrel,
bool deletion_ok);
static Node *pull_up_simple_subquery(PlannerInfo *root, Node *jtnode,
RangeTblEntry *rte,
JoinExpr *lowest_outer_join,
JoinExpr *lowest_nulling_outer_join,
AppendRelInfo *containing_appendrel,
bool deletion_ok);
static Node *pull_up_simple_union_all(PlannerInfo *root, Node *jtnode,
RangeTblEntry *rte);
static void pull_up_union_leaf_queries(Node *setOp, PlannerInfo *root,
int parentRTindex, Query *setOpQuery,
int childRToffset);
static void make_setop_translation_list(Query *query, Index newvarno,
List **translated_vars);
static bool is_simple_subquery(Query *subquery, RangeTblEntry *rte,
JoinExpr *lowest_outer_join,
bool deletion_ok);
static Node *pull_up_simple_values(PlannerInfo *root, Node *jtnode,
RangeTblEntry *rte);
static bool is_simple_values(PlannerInfo *root, RangeTblEntry *rte,
bool deletion_ok);
static bool is_simple_union_all(Query *subquery);
static bool is_simple_union_all_recurse(Node *setOp, Query *setOpQuery,
List *colTypes);
static bool is_safe_append_member(Query *subquery);
static bool jointree_contains_lateral_outer_refs(Node *jtnode, bool restricted,
Relids safe_upper_varnos);
static void replace_vars_in_jointree(Node *jtnode,
pullup_replace_vars_context *context,
JoinExpr *lowest_nulling_outer_join);
static Node *pullup_replace_vars(Node *expr,
pullup_replace_vars_context *context);
static Node *pullup_replace_vars_callback(Var *var,
replace_rte_variables_context *context);
static Query *pullup_replace_vars_subquery(Query *query,
pullup_replace_vars_context *context);
static Node *pull_up_subqueries_cleanup(Node *jtnode);
static reduce_outer_joins_state *reduce_outer_joins_pass1(Node *jtnode);
static void reduce_outer_joins_pass2(Node *jtnode,
reduce_outer_joins_state *state,
PlannerInfo *root,
Relids nonnullable_rels,
List *nonnullable_vars,
List *forced_null_vars);
static void substitute_multiple_relids(Node *node,
int varno, Relids subrelids);
static void fix_append_rel_relids(List *append_rel_list, int varno,
Relids subrelids);
static Node *find_jointree_node_for_rel(Node *jtnode, int relid);
/*
* pull_up_sublinks
* Attempt to pull up ANY and EXISTS SubLinks to be treated as
* semijoins or anti-semijoins.
*
* A clause "foo op ANY (sub-SELECT)" can be processed by pulling the
* sub-SELECT up to become a rangetable entry and treating the implied
* comparisons as quals of a semijoin. However, this optimization *only*
* works at the top level of WHERE or a JOIN/ON clause, because we cannot
* distinguish whether the ANY ought to return FALSE or NULL in cases
* involving NULL inputs. Also, in an outer join's ON clause we can only
* do this if the sublink is degenerate (ie, references only the nullable
* side of the join). In that case it is legal to push the semijoin
* down into the nullable side of the join. If the sublink references any
* nonnullable-side variables then it would have to be evaluated as part
* of the outer join, which makes things way too complicated.
*
* Under similar conditions, EXISTS and NOT EXISTS clauses can be handled
* by pulling up the sub-SELECT and creating a semijoin or anti-semijoin.
*
* This routine searches for such clauses and does the necessary parsetree
* transformations if any are found.
*
* This routine has to run before preprocess_expression(), so the quals
* clauses are not yet reduced to implicit-AND format, and are not guaranteed
* to be AND/OR-flat either. That means we need to recursively search through
* explicit AND clauses. We stop as soon as we hit a non-AND item.
*/
void
pull_up_sublinks(PlannerInfo *root)
{
Node *jtnode;
Relids relids;
/* Begin recursion through the jointree */
jtnode = pull_up_sublinks_jointree_recurse(root,
(Node *) root->parse->jointree,
&relids);
/*
* root->parse->jointree must always be a FromExpr, so insert a dummy one
* if we got a bare RangeTblRef or JoinExpr out of the recursion.
*/
if (IsA(jtnode, FromExpr))
root->parse->jointree = (FromExpr *) jtnode;
else
root->parse->jointree = makeFromExpr(list_make1(jtnode), NULL);
}
/*
* Recurse through jointree nodes for pull_up_sublinks()
*
* In addition to returning the possibly-modified jointree node, we return
* a relids set of the contained rels into *relids.
*/
static Node *
pull_up_sublinks_jointree_recurse(PlannerInfo *root, Node *jtnode,
Relids *relids)
{
if (jtnode == NULL)
{
*relids = NULL;
}
else if (IsA(jtnode, RangeTblRef))
{
int varno = ((RangeTblRef *) jtnode)->rtindex;
*relids = bms_make_singleton(varno);
/* jtnode is returned unmodified */
}
else if (IsA(jtnode, FromExpr))
{
FromExpr *f = (FromExpr *) jtnode;
List *newfromlist = NIL;
Relids frelids = NULL;
FromExpr *newf;
Node *jtlink;
ListCell *l;
/* First, recurse to process children and collect their relids */
foreach(l, f->fromlist)
{
Node *newchild;
Relids childrelids;
newchild = pull_up_sublinks_jointree_recurse(root,
lfirst(l),
&childrelids);
newfromlist = lappend(newfromlist, newchild);
frelids = bms_join(frelids, childrelids);
}
/* Build the replacement FromExpr; no quals yet */
newf = makeFromExpr(newfromlist, NULL);
/* Set up a link representing the rebuilt jointree */
jtlink = (Node *) newf;
/* Now process qual --- all children are available for use */
newf->quals = pull_up_sublinks_qual_recurse(root, f->quals,
&jtlink, frelids,
NULL, NULL);
/*
* Note that the result will be either newf, or a stack of JoinExprs
* with newf at the base. We rely on subsequent optimization steps to
* flatten this and rearrange the joins as needed.
*
* Although we could include the pulled-up subqueries in the returned
* relids, there's no need since upper quals couldn't refer to their
* outputs anyway.
*/
*relids = frelids;
jtnode = jtlink;
}
else if (IsA(jtnode, JoinExpr))
{
JoinExpr *j;
Relids leftrelids;
Relids rightrelids;
Node *jtlink;
/*
* Make a modifiable copy of join node, but don't bother copying its
* subnodes (yet).
*/
j = (JoinExpr *) palloc(sizeof(JoinExpr));
memcpy(j, jtnode, sizeof(JoinExpr));
jtlink = (Node *) j;
/* Recurse to process children and collect their relids */
j->larg = pull_up_sublinks_jointree_recurse(root, j->larg,
&leftrelids);
j->rarg = pull_up_sublinks_jointree_recurse(root, j->rarg,
&rightrelids);
/*
* Now process qual, showing appropriate child relids as available,
* and attach any pulled-up jointree items at the right place. In the
* inner-join case we put new JoinExprs above the existing one (much
* as for a FromExpr-style join). In outer-join cases the new
* JoinExprs must go into the nullable side of the outer join. The
* point of the available_rels machinations is to ensure that we only
* pull up quals for which that's okay.
*
* We don't expect to see any pre-existing JOIN_SEMI or JOIN_ANTI
* nodes here.
*/
switch (j->jointype)
{
case JOIN_INNER:
j->quals = pull_up_sublinks_qual_recurse(root, j->quals,
&jtlink,
bms_union(leftrelids,
rightrelids),
NULL, NULL);
break;
case JOIN_LEFT:
j->quals = pull_up_sublinks_qual_recurse(root, j->quals,
&j->rarg,
rightrelids,
NULL, NULL);
break;
case JOIN_FULL:
/* can't do anything with full-join quals */
break;
case JOIN_RIGHT:
j->quals = pull_up_sublinks_qual_recurse(root, j->quals,
&j->larg,
leftrelids,
NULL, NULL);
break;
default:
elog(ERROR, "unrecognized join type: %d",
(int) j->jointype);
break;
}
/*
* Although we could include the pulled-up subqueries in the returned
* relids, there's no need since upper quals couldn't refer to their
* outputs anyway. But we *do* need to include the join's own rtindex
* because we haven't yet collapsed join alias variables, so upper
* levels would mistakenly think they couldn't use references to this
* join.
*/
*relids = bms_join(leftrelids, rightrelids);
if (j->rtindex)
*relids = bms_add_member(*relids, j->rtindex);
jtnode = jtlink;
}
else
elog(ERROR, "unrecognized node type: %d",
(int) nodeTag(jtnode));
return jtnode;
}
/*
* Recurse through top-level qual nodes for pull_up_sublinks()
*
* jtlink1 points to the link in the jointree where any new JoinExprs should
* be inserted if they reference available_rels1 (i.e., available_rels1
* denotes the relations present underneath jtlink1). Optionally, jtlink2 can
* point to a second link where new JoinExprs should be inserted if they
* reference available_rels2 (pass NULL for both those arguments if not used).
* Note that SubLinks referencing both sets of variables cannot be optimized.
* If we find multiple pull-up-able SubLinks, they'll get stacked onto jtlink1
* and/or jtlink2 in the order we encounter them. We rely on subsequent
* optimization to rearrange the stack if appropriate.
*
* Returns the replacement qual node, or NULL if the qual should be removed.
*/
static Node *
pull_up_sublinks_qual_recurse(PlannerInfo *root, Node *node,
Node **jtlink1, Relids available_rels1,
Node **jtlink2, Relids available_rels2)
{
if (node == NULL)
return NULL;
if (IsA(node, SubLink))
{
SubLink *sublink = (SubLink *) node;
JoinExpr *j;
Relids child_rels;
/* Is it a convertible ANY or EXISTS clause? */
if (sublink->subLinkType == ANY_SUBLINK)
{
if ((j = convert_ANY_sublink_to_join(root, sublink,
available_rels1)) != NULL)
{
/* Yes; insert the new join node into the join tree */
j->larg = *jtlink1;
*jtlink1 = (Node *) j;
/* Recursively process pulled-up jointree nodes */
j->rarg = pull_up_sublinks_jointree_recurse(root,
j->rarg,
&child_rels);
/*
* Now recursively process the pulled-up quals. Any inserted
* joins can get stacked onto either j->larg or j->rarg,
* depending on which rels they reference.
*/
j->quals = pull_up_sublinks_qual_recurse(root,
j->quals,
&j->larg,
available_rels1,
&j->rarg,
child_rels);
/* Return NULL representing constant TRUE */
return NULL;
}
if (available_rels2 != NULL &&
(j = convert_ANY_sublink_to_join(root, sublink,
available_rels2)) != NULL)
{
/* Yes; insert the new join node into the join tree */
j->larg = *jtlink2;
*jtlink2 = (Node *) j;
/* Recursively process pulled-up jointree nodes */
j->rarg = pull_up_sublinks_jointree_recurse(root,
j->rarg,
&child_rels);
/*
* Now recursively process the pulled-up quals. Any inserted
* joins can get stacked onto either j->larg or j->rarg,
* depending on which rels they reference.
*/
j->quals = pull_up_sublinks_qual_recurse(root,
j->quals,
&j->larg,
available_rels2,
&j->rarg,
child_rels);
/* Return NULL representing constant TRUE */
return NULL;
}
}
else if (sublink->subLinkType == EXISTS_SUBLINK)
{
if ((j = convert_EXISTS_sublink_to_join(root, sublink, false,
available_rels1)) != NULL)
{
/* Yes; insert the new join node into the join tree */
j->larg = *jtlink1;
*jtlink1 = (Node *) j;
/* Recursively process pulled-up jointree nodes */
j->rarg = pull_up_sublinks_jointree_recurse(root,
j->rarg,
&child_rels);
/*
* Now recursively process the pulled-up quals. Any inserted
* joins can get stacked onto either j->larg or j->rarg,
* depending on which rels they reference.
*/
j->quals = pull_up_sublinks_qual_recurse(root,
j->quals,
&j->larg,
available_rels1,
&j->rarg,
child_rels);
/* Return NULL representing constant TRUE */
return NULL;
}
if (available_rels2 != NULL &&
(j = convert_EXISTS_sublink_to_join(root, sublink, false,
available_rels2)) != NULL)
{
/* Yes; insert the new join node into the join tree */
j->larg = *jtlink2;
*jtlink2 = (Node *) j;
/* Recursively process pulled-up jointree nodes */
j->rarg = pull_up_sublinks_jointree_recurse(root,
j->rarg,
&child_rels);
/*
* Now recursively process the pulled-up quals. Any inserted
* joins can get stacked onto either j->larg or j->rarg,
* depending on which rels they reference.
*/
j->quals = pull_up_sublinks_qual_recurse(root,
j->quals,
&j->larg,
available_rels2,
&j->rarg,
child_rels);
/* Return NULL representing constant TRUE */
return NULL;
}
}
/* Else return it unmodified */
return node;
}
if (not_clause(node))
{
/* If the immediate argument of NOT is EXISTS, try to convert */
SubLink *sublink = (SubLink *) get_notclausearg((Expr *) node);
JoinExpr *j;
Relids child_rels;
if (sublink && IsA(sublink, SubLink))
{
if (sublink->subLinkType == EXISTS_SUBLINK)
{
if ((j = convert_EXISTS_sublink_to_join(root, sublink, true,
available_rels1)) != NULL)
{
/* Yes; insert the new join node into the join tree */
j->larg = *jtlink1;
*jtlink1 = (Node *) j;
/* Recursively process pulled-up jointree nodes */
j->rarg = pull_up_sublinks_jointree_recurse(root,
j->rarg,
&child_rels);
/*
* Now recursively process the pulled-up quals. Because
* we are underneath a NOT, we can't pull up sublinks that
* reference the left-hand stuff, but it's still okay to
* pull up sublinks referencing j->rarg.
*/
j->quals = pull_up_sublinks_qual_recurse(root,
j->quals,
&j->rarg,
child_rels,
NULL, NULL);
/* Return NULL representing constant TRUE */
return NULL;
}
if (available_rels2 != NULL &&
(j = convert_EXISTS_sublink_to_join(root, sublink, true,
available_rels2)) != NULL)
{
/* Yes; insert the new join node into the join tree */
j->larg = *jtlink2;
*jtlink2 = (Node *) j;
/* Recursively process pulled-up jointree nodes */
j->rarg = pull_up_sublinks_jointree_recurse(root,
j->rarg,
&child_rels);
/*
* Now recursively process the pulled-up quals. Because
* we are underneath a NOT, we can't pull up sublinks that
* reference the left-hand stuff, but it's still okay to
* pull up sublinks referencing j->rarg.
*/
j->quals = pull_up_sublinks_qual_recurse(root,
j->quals,
&j->rarg,
child_rels,
NULL, NULL);
/* Return NULL representing constant TRUE */
return NULL;
}
}
}
/* Else return it unmodified */
return node;
}
if (and_clause(node))
{
/* Recurse into AND clause */
List *newclauses = NIL;
ListCell *l;
foreach(l, ((BoolExpr *) node)->args)
{
Node *oldclause = (Node *) lfirst(l);
Node *newclause;
newclause = pull_up_sublinks_qual_recurse(root,
oldclause,
jtlink1,
available_rels1,
jtlink2,
available_rels2);
if (newclause)
newclauses = lappend(newclauses, newclause);
}
/* We might have got back fewer clauses than we started with */
if (newclauses == NIL)
return NULL;
else if (list_length(newclauses) == 1)
return (Node *) linitial(newclauses);
else
return (Node *) make_andclause(newclauses);
}
/* Stop if not an AND */
return node;
}
/*
* inline_set_returning_functions
* Attempt to "inline" set-returning functions in the FROM clause.
*
* If an RTE_FUNCTION rtable entry invokes a set-returning function that
* contains just a simple SELECT, we can convert the rtable entry to an
* RTE_SUBQUERY entry exposing the SELECT directly. This is especially
* useful if the subquery can then be "pulled up" for further optimization,
* but we do it even if not, to reduce executor overhead.
*
* This has to be done before we have started to do any optimization of
* subqueries, else any such steps wouldn't get applied to subqueries
* obtained via inlining. However, we do it after pull_up_sublinks
* so that we can inline any functions used in SubLink subselects.
*
* Like most of the planner, this feels free to scribble on its input data
* structure.
*/
void
inline_set_returning_functions(PlannerInfo *root)
{
ListCell *rt;
foreach(rt, root->parse->rtable)
{
RangeTblEntry *rte = (RangeTblEntry *) lfirst(rt);
if (rte->rtekind == RTE_FUNCTION)
{
Query *funcquery;
/* Check safety of expansion, and expand if possible */
funcquery = inline_set_returning_function(root, rte);
if (funcquery)
{
/* Successful expansion, replace the rtable entry */
rte->rtekind = RTE_SUBQUERY;
rte->subquery = funcquery;
rte->functions = NIL;
}
}
}
}
/*
* pull_up_subqueries
* Look for subqueries in the rangetable that can be pulled up into
* the parent query. If the subquery has no special features like
* grouping/aggregation then we can merge it into the parent's jointree.
* Also, subqueries that are simple UNION ALL structures can be
* converted into "append relations".
*/
void
pull_up_subqueries(PlannerInfo *root)
{
/* Top level of jointree must always be a FromExpr */
Assert(IsA(root->parse->jointree, FromExpr));
/* Reset flag saying we need a deletion cleanup pass */
root->hasDeletedRTEs = false;
/* Recursion starts with no containing join nor appendrel */
root->parse->jointree = (FromExpr *)
pull_up_subqueries_recurse(root, (Node *) root->parse->jointree,
NULL, NULL, NULL, false);
/* Apply cleanup phase if necessary */
if (root->hasDeletedRTEs)
root->parse->jointree = (FromExpr *)
pull_up_subqueries_cleanup((Node *) root->parse->jointree);
Assert(IsA(root->parse->jointree, FromExpr));
}
/*
* pull_up_subqueries_recurse
* Recursive guts of pull_up_subqueries.
*
* This recursively processes the jointree and returns a modified jointree.
* Or, if it's valid to drop the current node from the jointree completely,
* it returns NULL.
*
* If this jointree node is within either side of an outer join, then
* lowest_outer_join references the lowest such JoinExpr node; otherwise
* it is NULL. We use this to constrain the effects of LATERAL subqueries.
*
* If this jointree node is within the nullable side of an outer join, then
* lowest_nulling_outer_join references the lowest such JoinExpr node;
* otherwise it is NULL. This forces use of the PlaceHolderVar mechanism for
* references to non-nullable targetlist items, but only for references above
* that join.
*
* If we are looking at a member subquery of an append relation,
* containing_appendrel describes that relation; else it is NULL.
* This forces use of the PlaceHolderVar mechanism for all non-Var targetlist
* items, and puts some additional restrictions on what can be pulled up.
*
* deletion_ok is true if the caller can cope with us returning NULL for a
* deletable leaf node (for example, a VALUES RTE that could be pulled up).
* If it's false, we'll avoid pullup in such cases.
*
* A tricky aspect of this code is that if we pull up a subquery we have
* to replace Vars that reference the subquery's outputs throughout the
* parent query, including quals attached to jointree nodes above the one
* we are currently processing! We handle this by being careful not to
* change the jointree structure while recursing: no nodes other than leaf
* RangeTblRef entries and entirely-empty FromExprs will be replaced or
* deleted. Also, we can't turn pullup_replace_vars loose on the whole
* jointree, because it'll return a mutated copy of the tree; we have to
* invoke it just on the quals, instead. This behavior is what makes it
* reasonable to pass lowest_outer_join and lowest_nulling_outer_join as
* pointers rather than some more-indirect way of identifying the lowest
* OJs. Likewise, we don't replace append_rel_list members but only their
* substructure, so the containing_appendrel reference is safe to use.
*
* Because of the rule that no jointree nodes with substructure can be
* replaced, we cannot fully handle the case of deleting nodes from the tree:
* when we delete one child of a JoinExpr, we need to replace the JoinExpr
* with a FromExpr, and that can't happen here. Instead, we set the
* root->hasDeletedRTEs flag, which tells pull_up_subqueries() that an
* additional pass over the tree is needed to clean up.
*/
static Node *
pull_up_subqueries_recurse(PlannerInfo *root, Node *jtnode,
JoinExpr *lowest_outer_join,
JoinExpr *lowest_nulling_outer_join,
AppendRelInfo *containing_appendrel,
bool deletion_ok)
{
Assert(jtnode != NULL);
if (IsA(jtnode, RangeTblRef))
{
int varno = ((RangeTblRef *) jtnode)->rtindex;
RangeTblEntry *rte = rt_fetch(varno, root->parse->rtable);
/*
* Is this a subquery RTE, and if so, is the subquery simple enough to
* pull up?
*
* If we are looking at an append-relation member, we can't pull it up
* unless is_safe_append_member says so.
*/
if (rte->rtekind == RTE_SUBQUERY &&
is_simple_subquery(rte->subquery, rte,
lowest_outer_join, deletion_ok) &&
(containing_appendrel == NULL ||
is_safe_append_member(rte->subquery)))
return pull_up_simple_subquery(root, jtnode, rte,
lowest_outer_join,
lowest_nulling_outer_join,
containing_appendrel,
deletion_ok);
/*
* Alternatively, is it a simple UNION ALL subquery? If so, flatten
* into an "append relation".
*
* It's safe to do this regardless of whether this query is itself an
* appendrel member. (If you're thinking we should try to flatten the
* two levels of appendrel together, you're right; but we handle that
* in set_append_rel_pathlist, not here.)
*/
if (rte->rtekind == RTE_SUBQUERY &&
is_simple_union_all(rte->subquery))
return pull_up_simple_union_all(root, jtnode, rte);
/*
* Or perhaps it's a simple VALUES RTE?
*
* We don't allow VALUES pullup below an outer join nor into an
* appendrel (such cases are impossible anyway at the moment).
*/
if (rte->rtekind == RTE_VALUES &&
lowest_outer_join == NULL &&
containing_appendrel == NULL &&
is_simple_values(root, rte, deletion_ok))
return pull_up_simple_values(root, jtnode, rte);
/* Otherwise, do nothing at this node. */
}
else if (IsA(jtnode, FromExpr))
{
FromExpr *f = (FromExpr *) jtnode;
bool have_undeleted_child = false;
ListCell *l;
Assert(containing_appendrel == NULL);
/*
* If the FromExpr has quals, it's not deletable even if its parent
* would allow deletion.
*/
if (f->quals)
deletion_ok = false;
foreach(l, f->fromlist)
{
/*
* In a non-deletable FromExpr, we can allow deletion of child
* nodes so long as at least one child remains; so it's okay
* either if any previous child survives, or if there's more to
* come. If all children are deletable in themselves, we'll force
* the last one to remain unflattened.
*
* As a separate matter, we can allow deletion of all children of
* the top-level FromExpr in a query, since that's a special case
* anyway.
*/
bool sub_deletion_ok = (deletion_ok ||
have_undeleted_child ||
lnext(l) != NULL ||
f == root->parse->jointree);
lfirst(l) = pull_up_subqueries_recurse(root, lfirst(l),
lowest_outer_join,
lowest_nulling_outer_join,
NULL,
sub_deletion_ok);
if (lfirst(l) != NULL)
have_undeleted_child = true;
}
if (deletion_ok && !have_undeleted_child)
{
/* OK to delete this FromExpr entirely */
root->hasDeletedRTEs = true; /* probably is set already */
return NULL;
}
}
else if (IsA(jtnode, JoinExpr))
{
JoinExpr *j = (JoinExpr *) jtnode;
Assert(containing_appendrel == NULL);
/* Recurse, being careful to tell myself when inside outer join */
switch (j->jointype)
{
case JOIN_INNER:
/*
* INNER JOIN can allow deletion of either child node, but not
* both. So right child gets permission to delete only if
* left child didn't get removed.
*/
j->larg = pull_up_subqueries_recurse(root, j->larg,
lowest_outer_join,
lowest_nulling_outer_join,
NULL,
true);
j->rarg = pull_up_subqueries_recurse(root, j->rarg,
lowest_outer_join,
lowest_nulling_outer_join,
NULL,
j->larg != NULL);
break;
case JOIN_LEFT:
case JOIN_SEMI:
case JOIN_ANTI:
j->larg = pull_up_subqueries_recurse(root, j->larg,
j,
lowest_nulling_outer_join,
NULL,
false);
j->rarg = pull_up_subqueries_recurse(root, j->rarg,
j,
j,
NULL,
false);
break;
case JOIN_FULL:
j->larg = pull_up_subqueries_recurse(root, j->larg,
j,
j,
NULL,
false);
j->rarg = pull_up_subqueries_recurse(root, j->rarg,
j,
j,
NULL,
false);
break;
case JOIN_RIGHT:
j->larg = pull_up_subqueries_recurse(root, j->larg,
j,
j,
NULL,
false);
j->rarg = pull_up_subqueries_recurse(root, j->rarg,
j,
lowest_nulling_outer_join,
NULL,
false);
break;
default:
elog(ERROR, "unrecognized join type: %d",
(int) j->jointype);
break;
}
}
else
elog(ERROR, "unrecognized node type: %d",
(int) nodeTag(jtnode));
return jtnode;
}
/*
* pull_up_simple_subquery
* Attempt to pull up a single simple subquery.
*
* jtnode is a RangeTblRef that has been tentatively identified as a simple
* subquery by pull_up_subqueries. We return the replacement jointree node,
* or NULL if the subquery can be deleted entirely, or jtnode itself if we
* determine that the subquery can't be pulled up after all.
*
* rte is the RangeTblEntry referenced by jtnode. Remaining parameters are
* as for pull_up_subqueries_recurse.
*/
static Node *
pull_up_simple_subquery(PlannerInfo *root, Node *jtnode, RangeTblEntry *rte,
JoinExpr *lowest_outer_join,
JoinExpr *lowest_nulling_outer_join,
AppendRelInfo *containing_appendrel,
bool deletion_ok)
{
Query *parse = root->parse;
int varno = ((RangeTblRef *) jtnode)->rtindex;
Query *subquery;
PlannerInfo *subroot;
int rtoffset;
pullup_replace_vars_context rvcontext;
ListCell *lc;
/*
* Need a modifiable copy of the subquery to hack on. Even if we didn't
* sometimes choose not to pull up below, we must do this to avoid
* problems if the same subquery is referenced from multiple jointree
* items (which can't happen normally, but might after rule rewriting).
*/
subquery = copyObject(rte->subquery);
/*
* Create a PlannerInfo data structure for this subquery.
*
* NOTE: the next few steps should match the first processing in
* subquery_planner(). Can we refactor to avoid code duplication, or
* would that just make things uglier?
*/
subroot = makeNode(PlannerInfo);
subroot->parse = subquery;
subroot->glob = root->glob;
subroot->query_level = root->query_level;
subroot->parent_root = root->parent_root;
subroot->plan_params = NIL;
subroot->outer_params = NULL;
subroot->planner_cxt = CurrentMemoryContext;
subroot->init_plans = NIL;
subroot->cte_plan_ids = NIL;
subroot->multiexpr_params = NIL;
subroot->eq_classes = NIL;
subroot->append_rel_list = NIL;
subroot->rowMarks = NIL;
memset(subroot->upper_rels, 0, sizeof(subroot->upper_rels));
memset(subroot->upper_targets, 0, sizeof(subroot->upper_targets));
subroot->processed_tlist = NIL;
subroot->grouping_map = NULL;
subroot->minmax_aggs = NIL;
subroot->qual_security_level = 0;
subroot->inhTargetKind = INHKIND_NONE;
subroot->hasRecursion = false;
subroot->wt_param_id = -1;
subroot->non_recursive_path = NULL;
/* No CTEs to worry about */
Assert(subquery->cteList == NIL);
/*
* Pull up any SubLinks within the subquery's quals, so that we don't
* leave unoptimized SubLinks behind.
*/
if (subquery->hasSubLinks)
pull_up_sublinks(subroot);
/*
* Similarly, inline any set-returning functions in its rangetable.
*/
inline_set_returning_functions(subroot);
/*
* Recursively pull up the subquery's subqueries, so that
* pull_up_subqueries' processing is complete for its jointree and
* rangetable.
*
* Note: it's okay that the subquery's recursion starts with NULL for
* containing-join info, even if we are within an outer join in the upper
* query; the lower query starts with a clean slate for outer-join
* semantics. Likewise, we needn't pass down appendrel state.
*/
pull_up_subqueries(subroot);
/*
* Now we must recheck whether the subquery is still simple enough to pull
* up. If not, abandon processing it.
*
* We don't really need to recheck all the conditions involved, but it's
* easier just to keep this "if" looking the same as the one in
* pull_up_subqueries_recurse.
*/
if (is_simple_subquery(subquery, rte,
lowest_outer_join, deletion_ok) &&
(containing_appendrel == NULL || is_safe_append_member(subquery)))
{
/* good to go */
}
else
{
/*
* Give up, return unmodified RangeTblRef.
*
* Note: The work we just did will be redone when the subquery gets
* planned on its own. Perhaps we could avoid that by storing the
* modified subquery back into the rangetable, but I'm not gonna risk
* it now.
*/
return jtnode;
}
/*
* We must flatten any join alias Vars in the subquery's targetlist,
* because pulling up the subquery's subqueries might have changed their
* expansions into arbitrary expressions, which could affect
* pullup_replace_vars' decisions about whether PlaceHolderVar wrappers
* are needed for tlist entries. (Likely it'd be better to do
* flatten_join_alias_vars on the whole query tree at some earlier stage,
* maybe even in the rewriter; but for now let's just fix this case here.)
*/
subquery->targetList = (List *)
flatten_join_alias_vars(subroot, (Node *) subquery->targetList);
/*
* Adjust level-0 varnos in subquery so that we can append its rangetable
* to upper query's. We have to fix the subquery's append_rel_list as
* well.
*/
rtoffset = list_length(parse->rtable);
OffsetVarNodes((Node *) subquery, rtoffset, 0);
OffsetVarNodes((Node *) subroot->append_rel_list, rtoffset, 0);
/*
* Upper-level vars in subquery are now one level closer to their parent
* than before.
*/
IncrementVarSublevelsUp((Node *) subquery, -1, 1);
IncrementVarSublevelsUp((Node *) subroot->append_rel_list, -1, 1);
/*
* The subquery's targetlist items are now in the appropriate form to
* insert into the top query, except that we may need to wrap them in
* PlaceHolderVars. Set up required context data for pullup_replace_vars.
*/
rvcontext.root = root;
rvcontext.targetlist = subquery->targetList;
rvcontext.target_rte = rte;
if (rte->lateral)
rvcontext.relids = get_relids_in_jointree((Node *) subquery->jointree,
true);
else /* won't need relids */
rvcontext.relids = NULL;
rvcontext.outer_hasSubLinks = &parse->hasSubLinks;
rvcontext.varno = varno;
/* these flags will be set below, if needed */
rvcontext.need_phvs = false;
rvcontext.wrap_non_vars = false;
/* initialize cache array with indexes 0 .. length(tlist) */
rvcontext.rv_cache = palloc0((list_length(subquery->targetList) + 1) *
sizeof(Node *));
/*
* If we are under an outer join then non-nullable items and lateral
* references may have to be turned into PlaceHolderVars.
*/
if (lowest_nulling_outer_join != NULL)
rvcontext.need_phvs = true;
/*
* If we are dealing with an appendrel member then anything that's not a
* simple Var has to be turned into a PlaceHolderVar. We force this to
* ensure that what we pull up doesn't get merged into a surrounding
* expression during later processing and then fail to match the
* expression actually available from the appendrel.
*/
if (containing_appendrel != NULL)
{
rvcontext.need_phvs = true;
rvcontext.wrap_non_vars = true;
}
/*
* If the parent query uses grouping sets, we need a PlaceHolderVar for
* anything that's not a simple Var. Again, this ensures that expressions
* retain their separate identity so that they will match grouping set
* columns when appropriate. (It'd be sufficient to wrap values used in
* grouping set columns, and do so only in non-aggregated portions of the
* tlist and havingQual, but that would require a lot of infrastructure
* that pullup_replace_vars hasn't currently got.)
*/
if (parse->groupingSets)
{
rvcontext.need_phvs = true;
rvcontext.wrap_non_vars = true;
}
/*
* Replace all of the top query's references to the subquery's outputs
* with copies of the adjusted subtlist items, being careful not to
* replace any of the jointree structure. (This'd be a lot cleaner if we
* could use query_tree_mutator.) We have to use PHVs in the targetList,
* returningList, and havingQual, since those are certainly above any
* outer join. replace_vars_in_jointree tracks its location in the
* jointree and uses PHVs or not appropriately.
*/
parse->targetList = (List *)
pullup_replace_vars((Node *) parse->targetList, &rvcontext);
parse->returningList = (List *)
pullup_replace_vars((Node *) parse->returningList, &rvcontext);
if (parse->onConflict)
{
parse->onConflict->onConflictSet = (List *)
pullup_replace_vars((Node *) parse->onConflict->onConflictSet,
&rvcontext);
parse->onConflict->onConflictWhere =
pullup_replace_vars(parse->onConflict->onConflictWhere,
&rvcontext);
/*
* We assume ON CONFLICT's arbiterElems, arbiterWhere, exclRelTlist
* can't contain any references to a subquery
*/
}
replace_vars_in_jointree((Node *) parse->jointree, &rvcontext,
lowest_nulling_outer_join);
Assert(parse->setOperations == NULL);
parse->havingQual = pullup_replace_vars(parse->havingQual, &rvcontext);
/*
* Replace references in the translated_vars lists of appendrels. When
* pulling up an appendrel member, we do not need PHVs in the list of the
* parent appendrel --- there isn't any outer join between. Elsewhere, use
* PHVs for safety. (This analysis could be made tighter but it seems
* unlikely to be worth much trouble.)
*/
foreach(lc, root->append_rel_list)
{
AppendRelInfo *appinfo = (AppendRelInfo *) lfirst(lc);
bool save_need_phvs = rvcontext.need_phvs;
if (appinfo == containing_appendrel)
rvcontext.need_phvs = false;
appinfo->translated_vars = (List *)
pullup_replace_vars((Node *) appinfo->translated_vars, &rvcontext);
rvcontext.need_phvs = save_need_phvs;
}
/*
* Replace references in the joinaliasvars lists of join RTEs.
*
* You might think that we could avoid using PHVs for alias vars of joins
* below lowest_nulling_outer_join, but that doesn't work because the
* alias vars could be referenced above that join; we need the PHVs to be
* present in such references after the alias vars get flattened. (It
* might be worth trying to be smarter here, someday.)
*/
foreach(lc, parse->rtable)
{
RangeTblEntry *otherrte = (RangeTblEntry *) lfirst(lc);
if (otherrte->rtekind == RTE_JOIN)
otherrte->joinaliasvars = (List *)
pullup_replace_vars((Node *) otherrte->joinaliasvars,
&rvcontext);
}
/*
* If the subquery had a LATERAL marker, propagate that to any of its
* child RTEs that could possibly now contain lateral cross-references.
* The children might or might not contain any actual lateral
* cross-references, but we have to mark the pulled-up child RTEs so that
* later planner stages will check for such.
*/
if (rte->lateral)
{
foreach(lc, subquery->rtable)
{
RangeTblEntry *child_rte = (RangeTblEntry *) lfirst(lc);
switch (child_rte->rtekind)
{
case RTE_RELATION:
if (child_rte->tablesample)
child_rte->lateral = true;
break;
case RTE_SUBQUERY:
case RTE_FUNCTION:
case RTE_VALUES:
case RTE_TABLEFUNC:
child_rte->lateral = true;
break;
case RTE_JOIN:
case RTE_CTE:
case RTE_NAMEDTUPLESTORE:
/* these can't contain any lateral references */
break;
}
}
}
/*
* Now append the adjusted rtable entries to upper query. (We hold off
* until after fixing the upper rtable entries; no point in running that
* code on the subquery ones too.)
*/
parse->rtable = list_concat(parse->rtable, subquery->rtable);
/*
* Pull up any FOR UPDATE/SHARE markers, too. (OffsetVarNodes already
* adjusted the marker rtindexes, so just concat the lists.)
*/
parse->rowMarks = list_concat(parse->rowMarks, subquery->rowMarks);
/*
* We also have to fix the relid sets of any PlaceHolderVar nodes in the
* parent query. (This could perhaps be done by pullup_replace_vars(),
* but it seems cleaner to use two passes.) Note in particular that any
* PlaceHolderVar nodes just created by pullup_replace_vars() will be
* adjusted, so having created them with the subquery's varno is correct.
*
* Likewise, relids appearing in AppendRelInfo nodes have to be fixed. We
* already checked that this won't require introducing multiple subrelids
* into the single-slot AppendRelInfo structs.
*/
if (parse->hasSubLinks || root->glob->lastPHId != 0 ||
root->append_rel_list)
{
Relids subrelids;
subrelids = get_relids_in_jointree((Node *) subquery->jointree, false);
substitute_multiple_relids((Node *) parse, varno, subrelids);
fix_append_rel_relids(root->append_rel_list, varno, subrelids);
}
/*
* And now add subquery's AppendRelInfos to our list.
*/
root->append_rel_list = list_concat(root->append_rel_list,
subroot->append_rel_list);
/*
* We don't have to do the equivalent bookkeeping for outer-join info,
* because that hasn't been set up yet. placeholder_list likewise.
*/
Assert(root->join_info_list == NIL);
Assert(subroot->join_info_list == NIL);
Assert(root->placeholder_list == NIL);
Assert(subroot->placeholder_list == NIL);
/*
* Miscellaneous housekeeping.
*
* Although replace_rte_variables() faithfully updated parse->hasSubLinks
* if it copied any SubLinks out of the subquery's targetlist, we still
* could have SubLinks added to the query in the expressions of FUNCTION
* and VALUES RTEs copied up from the subquery. So it's necessary to copy
* subquery->hasSubLinks anyway. Perhaps this can be improved someday.
*/
parse->hasSubLinks |= subquery->hasSubLinks;
/* If subquery had any RLS conditions, now main query does too */
parse->hasRowSecurity |= subquery->hasRowSecurity;
/*
* subquery won't be pulled up if it hasAggs, hasWindowFuncs, or
* hasTargetSRFs, so no work needed on those flags
*/
/*
* Return the adjusted subquery jointree to replace the RangeTblRef entry
* in parent's jointree; or, if we're flattening a subquery with empty
* FROM list, return NULL to signal deletion of the subquery from the
* parent jointree (and set hasDeletedRTEs to ensure cleanup later).
*/
if (subquery->jointree->fromlist == NIL)
{
Assert(deletion_ok);
Assert(subquery->jointree->quals == NULL);
root->hasDeletedRTEs = true;
return NULL;
}
return (Node *) subquery->jointree;
}
/*
* pull_up_simple_union_all
* Pull up a single simple UNION ALL subquery.
*
* jtnode is a RangeTblRef that has been identified as a simple UNION ALL
* subquery by pull_up_subqueries. We pull up the leaf subqueries and
* build an "append relation" for the union set. The result value is just
* jtnode, since we don't actually need to change the query jointree.
*/
static Node *
pull_up_simple_union_all(PlannerInfo *root, Node *jtnode, RangeTblEntry *rte)
{
int varno = ((RangeTblRef *) jtnode)->rtindex;
Query *subquery = rte->subquery;
int rtoffset = list_length(root->parse->rtable);
List *rtable;
/*
* Make a modifiable copy of the subquery's rtable, so we can adjust
* upper-level Vars in it. There are no such Vars in the setOperations
* tree proper, so fixing the rtable should be sufficient.
*/
rtable = copyObject(subquery->rtable);
/*
* Upper-level vars in subquery are now one level closer to their parent
* than before. We don't have to worry about offsetting varnos, though,
* because the UNION leaf queries can't cross-reference each other.
*/
IncrementVarSublevelsUp_rtable(rtable, -1, 1);
/*
* If the UNION ALL subquery had a LATERAL marker, propagate that to all
* its children. The individual children might or might not contain any
* actual lateral cross-references, but we have to mark the pulled-up
* child RTEs so that later planner stages will check for such.
*/
if (rte->lateral)
{
ListCell *rt;
foreach(rt, rtable)
{
RangeTblEntry *child_rte = (RangeTblEntry *) lfirst(rt);
Assert(child_rte->rtekind == RTE_SUBQUERY);
child_rte->lateral = true;
}
}
/*
* Append child RTEs to parent rtable.
*/
root->parse->rtable = list_concat(root->parse->rtable, rtable);
/*
* Recursively scan the subquery's setOperations tree and add
* AppendRelInfo nodes for leaf subqueries to the parent's
* append_rel_list. Also apply pull_up_subqueries to the leaf subqueries.
*/
Assert(subquery->setOperations);
pull_up_union_leaf_queries(subquery->setOperations, root, varno, subquery,
rtoffset);
/*
* Mark the parent as an append relation.
*/
rte->inh = true;
return jtnode;
}
/*
* pull_up_union_leaf_queries -- recursive guts of pull_up_simple_union_all
*
* Build an AppendRelInfo for each leaf query in the setop tree, and then
* apply pull_up_subqueries to the leaf query.
*
* Note that setOpQuery is the Query containing the setOp node, whose tlist
* contains references to all the setop output columns. When called from
* pull_up_simple_union_all, this is *not* the same as root->parse, which is
* the parent Query we are pulling up into.
*
* parentRTindex is the appendrel parent's index in root->parse->rtable.
*
* The child RTEs have already been copied to the parent. childRToffset
* tells us where in the parent's range table they were copied. When called
* from flatten_simple_union_all, childRToffset is 0 since the child RTEs
* were already in root->parse->rtable and no RT index adjustment is needed.
*/
static void
pull_up_union_leaf_queries(Node *setOp, PlannerInfo *root, int parentRTindex,
Query *setOpQuery, int childRToffset)
{
if (IsA(setOp, RangeTblRef))
{
RangeTblRef *rtr = (RangeTblRef *) setOp;
int childRTindex;
AppendRelInfo *appinfo;
/*
* Calculate the index in the parent's range table
*/
childRTindex = childRToffset + rtr->rtindex;
/*
* Build a suitable AppendRelInfo, and attach to parent's list.
*/
appinfo = makeNode(AppendRelInfo);
appinfo->parent_relid = parentRTindex;
appinfo->child_relid = childRTindex;
appinfo->parent_reltype = InvalidOid;
appinfo->child_reltype = InvalidOid;
make_setop_translation_list(setOpQuery, childRTindex,
&appinfo->translated_vars);
appinfo->parent_reloid = InvalidOid;
root->append_rel_list = lappend(root->append_rel_list, appinfo);
/*
* Recursively apply pull_up_subqueries to the new child RTE. (We
* must build the AppendRelInfo first, because this will modify it.)
* Note that we can pass NULL for containing-join info even if we're
* actually under an outer join, because the child's expressions
* aren't going to propagate up to the join. Also, we ignore the
* possibility that pull_up_subqueries_recurse() returns a different
* jointree node than what we pass it; if it does, the important thing
* is that it replaced the child relid in the AppendRelInfo node.
*/
rtr = makeNode(RangeTblRef);
rtr->rtindex = childRTindex;
(void) pull_up_subqueries_recurse(root, (Node *) rtr,
NULL, NULL, appinfo, false);
}
else if (IsA(setOp, SetOperationStmt))
{
SetOperationStmt *op = (SetOperationStmt *) setOp;
/* Recurse to reach leaf queries */
pull_up_union_leaf_queries(op->larg, root, parentRTindex, setOpQuery,
childRToffset);
pull_up_union_leaf_queries(op->rarg, root, parentRTindex, setOpQuery,
childRToffset);
}
else
{
elog(ERROR, "unrecognized node type: %d",
(int) nodeTag(setOp));
}
}
/*
* make_setop_translation_list
* Build the list of translations from parent Vars to child Vars for
* a UNION ALL member. (At this point it's just a simple list of
* referencing Vars, but if we succeed in pulling up the member
* subquery, the Vars will get replaced by pulled-up expressions.)
*/
static void
make_setop_translation_list(Query *query, Index newvarno,
List **translated_vars)
{
List *vars = NIL;
ListCell *l;
foreach(l, query->targetList)
{
TargetEntry *tle = (TargetEntry *) lfirst(l);
if (tle->resjunk)
continue;
vars = lappend(vars, makeVarFromTargetEntry(newvarno, tle));
}
*translated_vars = vars;
}
/*
* is_simple_subquery
* Check a subquery in the range table to see if it's simple enough
* to pull up into the parent query.
*
* rte is the RTE_SUBQUERY RangeTblEntry that contained the subquery.
* (Note subquery is not necessarily equal to rte->subquery; it could be a
* processed copy of that.)
* lowest_outer_join is the lowest outer join above the subquery, or NULL.
* deletion_ok is true if it'd be okay to delete the subquery entirely.
*/
static bool
is_simple_subquery(Query *subquery, RangeTblEntry *rte,
JoinExpr *lowest_outer_join,
bool deletion_ok)
{
/*
* Let's just make sure it's a valid subselect ...
*/
if (!IsA(subquery, Query) ||
subquery->commandType != CMD_SELECT)
elog(ERROR, "subquery is bogus");
/*
* Can't currently pull up a query with setops (unless it's simple UNION
* ALL, which is handled by a different code path). Maybe after querytree
* redesign...
*/
if (subquery->setOperations)
return false;
/*
* Can't pull up a subquery involving grouping, aggregation, SRFs,
* sorting, limiting, or WITH. (XXX WITH could possibly be allowed later)
*
* We also don't pull up a subquery that has explicit FOR UPDATE/SHARE
* clauses, because pullup would cause the locking to occur semantically
* higher than it should. Implicit FOR UPDATE/SHARE is okay because in
* that case the locking was originally declared in the upper query
* anyway.
*/
if (subquery->hasAggs ||
subquery->hasWindowFuncs ||
subquery->hasTargetSRFs ||
subquery->groupClause ||
subquery->groupingSets ||
subquery->havingQual ||
subquery->sortClause ||
subquery->distinctClause ||
subquery->limitOffset ||
subquery->limitCount ||
subquery->hasForUpdate ||
subquery->cteList)
return false;
/*
* Don't pull up if the RTE represents a security-barrier view; we
* couldn't prevent information leakage once the RTE's Vars are scattered
* about in the upper query.
*/
if (rte->security_barrier)
return false;
/*
* Don't pull up a subquery with an empty jointree, unless it has no quals
* and deletion_ok is true and we're not underneath an outer join.
*
* query_planner() will correctly generate a Result plan for a jointree
* that's totally empty, but we can't cope with an empty FromExpr
* appearing lower down in a jointree: we identify join rels via baserelid
* sets, so we couldn't distinguish a join containing such a FromExpr from
* one without it. We can only handle such cases if the place where the
* subquery is linked is a FromExpr or inner JOIN that would still be
* nonempty after removal of the subquery, so that it's still identifiable
* via its contained baserelids. Safe contexts are signaled by
* deletion_ok.
*
* But even in a safe context, we must keep the subquery if it has any
* quals, because it's unclear where to put them in the upper query.
*
* Also, we must forbid pullup if such a subquery is underneath an outer
* join, because then we might need to wrap its output columns with
* PlaceHolderVars, and the PHVs would then have empty relid sets meaning
* we couldn't tell where to evaluate them. (This test is separate from
* the deletion_ok flag for possible future expansion: deletion_ok tells
* whether the immediate parent site in the jointree could cope, not
* whether we'd have PHV issues. It's possible this restriction could be
* fixed by letting the PHVs use the relids of the parent jointree item,
* but that complication is for another day.)
*
* Note that deletion of a subquery is also dependent on the check below
* that its targetlist contains no set-returning functions. Deletion from
* a FROM list or inner JOIN is okay only if the subquery must return
* exactly one row.
*/
if (subquery->jointree->fromlist == NIL &&
(subquery->jointree->quals != NULL ||
!deletion_ok ||
lowest_outer_join != NULL))
return false;
/*
* If the subquery is LATERAL, check for pullup restrictions from that.
*/
if (rte->lateral)
{
bool restricted;
Relids safe_upper_varnos;
/*
* The subquery's WHERE and JOIN/ON quals mustn't contain any lateral
* references to rels outside a higher outer join (including the case
* where the outer join is within the subquery itself). In such a
* case, pulling up would result in a situation where we need to
* postpone quals from below an outer join to above it, which is
* probably completely wrong and in any case is a complication that
* doesn't seem worth addressing at the moment.
*/
if (lowest_outer_join != NULL)
{
restricted = true;
safe_upper_varnos = get_relids_in_jointree((Node *) lowest_outer_join,
true);
}
else
{
restricted = false;
safe_upper_varnos = NULL; /* doesn't matter */
}
if (jointree_contains_lateral_outer_refs((Node *) subquery->jointree,
restricted, safe_upper_varnos))
return false;
/*
* If there's an outer join above the LATERAL subquery, also disallow
* pullup if the subquery's targetlist has any references to rels
* outside the outer join, since these might get pulled into quals
* above the subquery (but in or below the outer join) and then lead
* to qual-postponement issues similar to the case checked for above.
* (We wouldn't need to prevent pullup if no such references appear in
* outer-query quals, but we don't have enough info here to check
* that. Also, maybe this restriction could be removed if we forced
* such refs to be wrapped in PlaceHolderVars, even when they're below
* the nearest outer join? But it's a pretty hokey usage, so not
* clear this is worth sweating over.)
*/
if (lowest_outer_join != NULL)
{
Relids lvarnos = pull_varnos_of_level((Node *) subquery->targetList, 1);
if (!bms_is_subset(lvarnos, safe_upper_varnos))
return false;
}
}
/*
* Don't pull up a subquery that has any volatile functions in its
* targetlist. Otherwise we might introduce multiple evaluations of these
* functions, if they get copied to multiple places in the upper query,
* leading to surprising results. (Note: the PlaceHolderVar mechanism
* doesn't quite guarantee single evaluation; else we could pull up anyway
* and just wrap such items in PlaceHolderVars ...)
*/
if (contain_volatile_functions((Node *) subquery->targetList))
return false;
return true;
}
/*
* pull_up_simple_values
* Pull up a single simple VALUES RTE.
*
* jtnode is a RangeTblRef that has been identified as a simple VALUES RTE
* by pull_up_subqueries. We always return NULL indicating that the RTE
* can be deleted entirely (all failure cases should have been detected by
* is_simple_values()).
*
* rte is the RangeTblEntry referenced by jtnode. Because of the limited
* possible usage of VALUES RTEs, we do not need the remaining parameters
* of pull_up_subqueries_recurse.
*/
static Node *
pull_up_simple_values(PlannerInfo *root, Node *jtnode, RangeTblEntry *rte)
{
Query *parse = root->parse;
int varno = ((RangeTblRef *) jtnode)->rtindex;
List *values_list;
List *tlist;
AttrNumber attrno;
pullup_replace_vars_context rvcontext;
ListCell *lc;
Assert(rte->rtekind == RTE_VALUES);
Assert(list_length(rte->values_lists) == 1);
/*
* Need a modifiable copy of the VALUES list to hack on, just in case it's
* multiply referenced.
*/
values_list = copyObject(linitial(rte->values_lists));
/*
* The VALUES RTE can't contain any Vars of level zero, let alone any that
* are join aliases, so no need to flatten join alias Vars.
*/
Assert(!contain_vars_of_level((Node *) values_list, 0));
/*
* Set up required context data for pullup_replace_vars. In particular,
* we have to make the VALUES list look like a subquery targetlist.
*/
tlist = NIL;
attrno = 1;
foreach(lc, values_list)
{
tlist = lappend(tlist,
makeTargetEntry((Expr *) lfirst(lc),
attrno,
NULL,
false));
attrno++;
}
rvcontext.root = root;
rvcontext.targetlist = tlist;
rvcontext.target_rte = rte;
rvcontext.relids = NULL;
rvcontext.outer_hasSubLinks = &parse->hasSubLinks;
rvcontext.varno = varno;
rvcontext.need_phvs = false;
rvcontext.wrap_non_vars = false;
/* initialize cache array with indexes 0 .. length(tlist) */
rvcontext.rv_cache = palloc0((list_length(tlist) + 1) *
sizeof(Node *));
/*
* Replace all of the top query's references to the RTE's outputs with
* copies of the adjusted VALUES expressions, being careful not to replace
* any of the jointree structure. (This'd be a lot cleaner if we could use
* query_tree_mutator.) Much of this should be no-ops in the dummy Query
* that surrounds a VALUES RTE, but it's not enough code to be worth
* removing.
*/
parse->targetList = (List *)
pullup_replace_vars((Node *) parse->targetList, &rvcontext);
parse->returningList = (List *)
pullup_replace_vars((Node *) parse->returningList, &rvcontext);
if (parse->onConflict)
{
parse->onConflict->onConflictSet = (List *)
pullup_replace_vars((Node *) parse->onConflict->onConflictSet,
&rvcontext);
parse->onConflict->onConflictWhere =
pullup_replace_vars(parse->onConflict->onConflictWhere,
&rvcontext);
/*
* We assume ON CONFLICT's arbiterElems, arbiterWhere, exclRelTlist
* can't contain any references to a subquery
*/
}
replace_vars_in_jointree((Node *) parse->jointree, &rvcontext, NULL);
Assert(parse->setOperations == NULL);
parse->havingQual = pullup_replace_vars(parse->havingQual, &rvcontext);
/*
* There should be no appendrels to fix, nor any join alias Vars, nor any
* outer joins and hence no PlaceHolderVars.
*/
Assert(root->append_rel_list == NIL);
Assert(list_length(parse->rtable) == 1);
Assert(root->join_info_list == NIL);
Assert(root->placeholder_list == NIL);
/*
* Return NULL to signal deletion of the VALUES RTE from the parent
* jointree (and set hasDeletedRTEs to ensure cleanup later).
*/
root->hasDeletedRTEs = true;
return NULL;
}
/*
* is_simple_values
* Check a VALUES RTE in the range table to see if it's simple enough
* to pull up into the parent query.
*
* rte is the RTE_VALUES RangeTblEntry to check.
* deletion_ok is true if it'd be okay to delete the VALUES RTE entirely.
*/
static bool
is_simple_values(PlannerInfo *root, RangeTblEntry *rte, bool deletion_ok)
{
Assert(rte->rtekind == RTE_VALUES);
/*
* We can only pull up a VALUES RTE if deletion_ok is true. It's
* basically the same case as a sub-select with empty FROM list; see
* comments in is_simple_subquery().
*/
if (!deletion_ok)
return false;
/*
* Also, there must be exactly one VALUES list, else it's not semantically
* correct to delete the VALUES RTE.
*/
if (list_length(rte->values_lists) != 1)
return false;
/*
* Because VALUES can't appear under an outer join (or at least, we won't
* try to pull it up if it does), we need not worry about LATERAL, nor
* about validity of PHVs for the VALUES' outputs.
*/
/*
* Don't pull up a VALUES that contains any set-returning or volatile
* functions. Again, the considerations here are basically identical to
* restrictions on a subquery's targetlist.
*/
if (expression_returns_set((Node *) rte->values_lists) ||
contain_volatile_functions((Node *) rte->values_lists))
return false;
/*
* Do not pull up a VALUES that's not the only RTE in its parent query.
* This is actually the only case that the parser will generate at the
* moment, and assuming this is true greatly simplifies
* pull_up_simple_values().
*/
if (list_length(root->parse->rtable) != 1 ||
rte != (RangeTblEntry *) linitial(root->parse->rtable))
return false;
return true;
}
/*
* is_simple_union_all
* Check a subquery to see if it's a simple UNION ALL.
*
* We require all the setops to be UNION ALL (no mixing) and there can't be
* any datatype coercions involved, ie, all the leaf queries must emit the
* same datatypes.
*/
static bool
is_simple_union_all(Query *subquery)
{
SetOperationStmt *topop;
/* Let's just make sure it's a valid subselect ... */
if (!IsA(subquery, Query) ||
subquery->commandType != CMD_SELECT)
elog(ERROR, "subquery is bogus");
/* Is it a set-operation query at all? */
topop = castNode(SetOperationStmt, subquery->setOperations);
if (!topop)
return false;
/* Can't handle ORDER BY, LIMIT/OFFSET, locking, or WITH */
if (subquery->sortClause ||
subquery->limitOffset ||
subquery->limitCount ||
subquery->rowMarks ||
subquery->cteList)
return false;
/* Recursively check the tree of set operations */
return is_simple_union_all_recurse((Node *) topop, subquery,
topop->colTypes);
}
static bool
is_simple_union_all_recurse(Node *setOp, Query *setOpQuery, List *colTypes)
{
if (IsA(setOp, RangeTblRef))
{
RangeTblRef *rtr = (RangeTblRef *) setOp;
RangeTblEntry *rte = rt_fetch(rtr->rtindex, setOpQuery->rtable);
Query *subquery = rte->subquery;
Assert(subquery != NULL);
/* Leaf nodes are OK if they match the toplevel column types */
/* We don't have to compare typmods or collations here */
return tlist_same_datatypes(subquery->targetList, colTypes, true);
}
else if (IsA(setOp, SetOperationStmt))
{
SetOperationStmt *op = (SetOperationStmt *) setOp;
/* Must be UNION ALL */
if (op->op != SETOP_UNION || !op->all)
return false;
/* Recurse to check inputs */
return is_simple_union_all_recurse(op->larg, setOpQuery, colTypes) &&
is_simple_union_all_recurse(op->rarg, setOpQuery, colTypes);
}
else
{
elog(ERROR, "unrecognized node type: %d",
(int) nodeTag(setOp));
return false; /* keep compiler quiet */
}
}
/*
* is_safe_append_member
* Check a subquery that is a leaf of a UNION ALL appendrel to see if it's
* safe to pull up.
*/
static bool
is_safe_append_member(Query *subquery)
{
FromExpr *jtnode;
/*
* It's only safe to pull up the child if its jointree contains exactly
* one RTE, else the AppendRelInfo data structure breaks. The one base RTE
* could be buried in several levels of FromExpr, however.
*
* Also, the child can't have any WHERE quals because there's no place to
* put them in an appendrel. (This is a bit annoying...) If we didn't
* need to check this, we'd just test whether get_relids_in_jointree()
* yields a singleton set, to be more consistent with the coding of
* fix_append_rel_relids().
*/
jtnode = subquery->jointree;
while (IsA(jtnode, FromExpr))
{
if (jtnode->quals != NULL)
return false;
if (list_length(jtnode->fromlist) != 1)
return false;
jtnode = linitial(jtnode->fromlist);
}
if (!IsA(jtnode, RangeTblRef))
return false;
return true;
}
/*
* jointree_contains_lateral_outer_refs
* Check for disallowed lateral references in a jointree's quals
*
* If restricted is false, all level-1 Vars are allowed (but we still must
* search the jointree, since it might contain outer joins below which there
* will be restrictions). If restricted is true, return true when any qual
* in the jointree contains level-1 Vars coming from outside the rels listed
* in safe_upper_varnos.
*/
static bool
jointree_contains_lateral_outer_refs(Node *jtnode, bool restricted,
Relids safe_upper_varnos)
{
if (jtnode == NULL)
return false;
if (IsA(jtnode, RangeTblRef))
return false;
else if (IsA(jtnode, FromExpr))
{
FromExpr *f = (FromExpr *) jtnode;
ListCell *l;
/* First, recurse to check child joins */
foreach(l, f->fromlist)
{
if (jointree_contains_lateral_outer_refs(lfirst(l),
restricted,
safe_upper_varnos))
return true;
}
/* Then check the top-level quals */
if (restricted &&
!bms_is_subset(pull_varnos_of_level(f->quals, 1),
safe_upper_varnos))
return true;
}
else if (IsA(jtnode, JoinExpr))
{
JoinExpr *j = (JoinExpr *) jtnode;
/*
* If this is an outer join, we mustn't allow any upper lateral
* references in or below it.
*/
if (j->jointype != JOIN_INNER)
{
restricted = true;
safe_upper_varnos = NULL;
}
/* Check the child joins */
if (jointree_contains_lateral_outer_refs(j->larg,
restricted,
safe_upper_varnos))
return true;
if (jointree_contains_lateral_outer_refs(j->rarg,
restricted,
safe_upper_varnos))
return true;
/* Check the JOIN's qual clauses */
if (restricted &&
!bms_is_subset(pull_varnos_of_level(j->quals, 1),
safe_upper_varnos))
return true;
}
else
elog(ERROR, "unrecognized node type: %d",
(int) nodeTag(jtnode));
return false;
}
/*
* Helper routine for pull_up_subqueries: do pullup_replace_vars on every
* expression in the jointree, without changing the jointree structure itself.
* Ugly, but there's no other way...
*
* If we are at or below lowest_nulling_outer_join, we can suppress use of
* PlaceHolderVars wrapped around the replacement expressions.
*/
static void
replace_vars_in_jointree(Node *jtnode,
pullup_replace_vars_context *context,
JoinExpr *lowest_nulling_outer_join)
{
if (jtnode == NULL)
return;
if (IsA(jtnode, RangeTblRef))
{
/*
* If the RangeTblRef refers to a LATERAL subquery (that isn't the
* same subquery we're pulling up), it might contain references to the
* target subquery, which we must replace. We drive this from the
* jointree scan, rather than a scan of the rtable, for a couple of
* reasons: we can avoid processing no-longer-referenced RTEs, and we
* can use the appropriate setting of need_phvs depending on whether
* the RTE is above possibly-nulling outer joins or not.
*/
int varno = ((RangeTblRef *) jtnode)->rtindex;
if (varno != context->varno) /* ignore target subquery itself */
{
RangeTblEntry *rte = rt_fetch(varno, context->root->parse->rtable);
Assert(rte != context->target_rte);
if (rte->lateral)
{
switch (rte->rtekind)
{
case RTE_RELATION:
/* shouldn't be marked LATERAL unless tablesample */
Assert(rte->tablesample);
rte->tablesample = (TableSampleClause *)
pullup_replace_vars((Node *) rte->tablesample,
context);
break;
case RTE_SUBQUERY:
rte->subquery =
pullup_replace_vars_subquery(rte->subquery,
context);
break;
case RTE_FUNCTION:
rte->functions = (List *)
pullup_replace_vars((Node *) rte->functions,
context);
break;
case RTE_TABLEFUNC:
rte->tablefunc = (TableFunc *)
pullup_replace_vars((Node *) rte->tablefunc,
context);
break;
case RTE_VALUES:
rte->values_lists = (List *)
pullup_replace_vars((Node *) rte->values_lists,
context);
break;
case RTE_JOIN:
case RTE_CTE:
case RTE_NAMEDTUPLESTORE:
/* these shouldn't be marked LATERAL */
Assert(false);
break;
}
}
}
}
else if (IsA(jtnode, FromExpr))
{
FromExpr *f = (FromExpr *) jtnode;
ListCell *l;
foreach(l, f->fromlist)
replace_vars_in_jointree(lfirst(l), context,
lowest_nulling_outer_join);
f->quals = pullup_replace_vars(f->quals, context);
}
else if (IsA(jtnode, JoinExpr))
{
JoinExpr *j = (JoinExpr *) jtnode;
bool save_need_phvs = context->need_phvs;
if (j == lowest_nulling_outer_join)
{
/* no more PHVs in or below this join */
context->need_phvs = false;
lowest_nulling_outer_join = NULL;
}
replace_vars_in_jointree(j->larg, context, lowest_nulling_outer_join);
replace_vars_in_jointree(j->rarg, context, lowest_nulling_outer_join);
j->quals = pullup_replace_vars(j->quals, context);
/*
* We don't bother to update the colvars list, since it won't be used
* again ...
*/
context->need_phvs = save_need_phvs;
}
else
elog(ERROR, "unrecognized node type: %d",
(int) nodeTag(jtnode));
}
/*
* Apply pullup variable replacement throughout an expression tree
*
* Returns a modified copy of the tree, so this can't be used where we
* need to do in-place replacement.
*/
static Node *
pullup_replace_vars(Node *expr, pullup_replace_vars_context *context)
{
return replace_rte_variables(expr,
context->varno, 0,
pullup_replace_vars_callback,
(void *) context,
context->outer_hasSubLinks);
}
static Node *
pullup_replace_vars_callback(Var *var,
replace_rte_variables_context *context)
{
pullup_replace_vars_context *rcon = (pullup_replace_vars_context *) context->callback_arg;
int varattno = var->varattno;
Node *newnode;
/*
* If PlaceHolderVars are needed, we cache the modified expressions in
* rcon->rv_cache[]. This is not in hopes of any material speed gain
* within this function, but to avoid generating identical PHVs with
* different IDs. That would result in duplicate evaluations at runtime,
* and possibly prevent optimizations that rely on recognizing different
* references to the same subquery output as being equal(). So it's worth
* a bit of extra effort to avoid it.
*/
if (rcon->need_phvs &&
varattno >= InvalidAttrNumber &&
varattno <= list_length(rcon->targetlist) &&
rcon->rv_cache[varattno] != NULL)
{
/* Just copy the entry and fall through to adjust its varlevelsup */
newnode = copyObject(rcon->rv_cache[varattno]);
}
else if (varattno == InvalidAttrNumber)
{
/* Must expand whole-tuple reference into RowExpr */
RowExpr *rowexpr;
List *colnames;
List *fields;
bool save_need_phvs = rcon->need_phvs;
int save_sublevelsup = context->sublevels_up;
/*
* If generating an expansion for a var of a named rowtype (ie, this
* is a plain relation RTE), then we must include dummy items for
* dropped columns. If the var is RECORD (ie, this is a JOIN), then
* omit dropped columns. Either way, attach column names to the
* RowExpr for use of ruleutils.c.
*
* In order to be able to cache the results, we always generate the
* expansion with varlevelsup = 0, and then adjust if needed.
*/
expandRTE(rcon->target_rte,
var->varno, 0 /* not varlevelsup */ , var->location,
(var->vartype != RECORDOID),
&colnames, &fields);
/* Adjust the generated per-field Vars, but don't insert PHVs */
rcon->need_phvs = false;
context->sublevels_up = 0; /* to match the expandRTE output */
fields = (List *) replace_rte_variables_mutator((Node *) fields,
context);
rcon->need_phvs = save_need_phvs;
context->sublevels_up = save_sublevelsup;
rowexpr = makeNode(RowExpr);
rowexpr->args = fields;
rowexpr->row_typeid = var->vartype;
rowexpr->row_format = COERCE_IMPLICIT_CAST;
rowexpr->colnames = colnames;
rowexpr->location = var->location;
newnode = (Node *) rowexpr;
/*
* Insert PlaceHolderVar if needed. Notice that we are wrapping one
* PlaceHolderVar around the whole RowExpr, rather than putting one
* around each element of the row. This is because we need the
* expression to yield NULL, not ROW(NULL,NULL,...) when it is forced
* to null by an outer join.
*/
if (rcon->need_phvs)
{
/* RowExpr is certainly not strict, so always need PHV */
newnode = (Node *)
make_placeholder_expr(rcon->root,
(Expr *) newnode,
bms_make_singleton(rcon->varno));
/* cache it with the PHV, and with varlevelsup still zero */
rcon->rv_cache[InvalidAttrNumber] = copyObject(newnode);
}
}
else
{
/* Normal case referencing one targetlist element */
TargetEntry *tle = get_tle_by_resno(rcon->targetlist, varattno);
if (tle == NULL) /* shouldn't happen */
elog(ERROR, "could not find attribute %d in subquery targetlist",
varattno);
/* Make a copy of the tlist item to return */
newnode = (Node *) copyObject(tle->expr);
/* Insert PlaceHolderVar if needed */
if (rcon->need_phvs)
{
bool wrap;
if (newnode && IsA(newnode, Var) &&
((Var *) newnode)->varlevelsup == 0)
{
/*
* Simple Vars always escape being wrapped, unless they are
* lateral references to something outside the subquery being
* pulled up. (Even then, we could omit the PlaceHolderVar if
* the referenced rel is under the same lowest outer join, but
* it doesn't seem worth the trouble to check that.)
*/
if (rcon->target_rte->lateral &&
!bms_is_member(((Var *) newnode)->varno, rcon->relids))
wrap = true;
else
wrap = false;
}
else if (newnode && IsA(newnode, PlaceHolderVar) &&
((PlaceHolderVar *) newnode)->phlevelsup == 0)
{
/* No need to wrap a PlaceHolderVar with another one, either */
wrap = false;
}
else if (rcon->wrap_non_vars)
{
/* Wrap all non-Vars in a PlaceHolderVar */
wrap = true;
}
else
{
/*
* If it contains a Var of the subquery being pulled up, and
* does not contain any non-strict constructs, then it's
* certainly nullable so we don't need to insert a
* PlaceHolderVar.
*
* This analysis could be tighter: in particular, a non-strict
* construct hidden within a lower-level PlaceHolderVar is not
* reason to add another PHV. But for now it doesn't seem
* worth the code to be more exact.
*
* Note: in future maybe we should insert a PlaceHolderVar
* anyway, if the tlist item is expensive to evaluate?
*
* For a LATERAL subquery, we have to check the actual var
* membership of the node, but if it's non-lateral then any
* level-zero var must belong to the subquery.
*/
if ((rcon->target_rte->lateral ?
bms_overlap(pull_varnos((Node *) newnode), rcon->relids) :
contain_vars_of_level((Node *) newnode, 0)) &&
!contain_nonstrict_functions((Node *) newnode))
{
/* No wrap needed */
wrap = false;
}
else
{
/* Else wrap it in a PlaceHolderVar */
wrap = true;
}
}
if (wrap)
newnode = (Node *)
make_placeholder_expr(rcon->root,
(Expr *) newnode,
bms_make_singleton(rcon->varno));
/*
* Cache it if possible (ie, if the attno is in range, which it
* probably always should be). We can cache the value even if we
* decided we didn't need a PHV, since this result will be
* suitable for any request that has need_phvs.
*/
if (varattno > InvalidAttrNumber &&
varattno <= list_length(rcon->targetlist))
rcon->rv_cache[varattno] = copyObject(newnode);
}
}
/* Must adjust varlevelsup if tlist item is from higher query */
if (var->varlevelsup > 0)
IncrementVarSublevelsUp(newnode, var->varlevelsup, 0);
return newnode;
}
/*
* Apply pullup variable replacement to a subquery
*
* This needs to be different from pullup_replace_vars() because
* replace_rte_variables will think that it shouldn't increment sublevels_up
* before entering the Query; so we need to call it with sublevels_up == 1.
*/
static Query *
pullup_replace_vars_subquery(Query *query,
pullup_replace_vars_context *context)
{
Assert(IsA(query, Query));
return (Query *) replace_rte_variables((Node *) query,
context->varno, 1,
pullup_replace_vars_callback,
(void *) context,
NULL);
}
/*
* pull_up_subqueries_cleanup
* Recursively fix up jointree after deletion of some subqueries.
*
* The jointree now contains some NULL subtrees, which we need to get rid of.
* In a FromExpr, just rebuild the child-node list with null entries deleted.
* In an inner JOIN, replace the JoinExpr node with a one-child FromExpr.
*/
static Node *
pull_up_subqueries_cleanup(Node *jtnode)
{
Assert(jtnode != NULL);
if (IsA(jtnode, RangeTblRef))
{
/* Nothing to do at leaf nodes. */
}
else if (IsA(jtnode, FromExpr))
{
FromExpr *f = (FromExpr *) jtnode;
List *newfrom = NIL;
ListCell *l;
foreach(l, f->fromlist)
{
Node *child = (Node *) lfirst(l);
if (child == NULL)
continue;
child = pull_up_subqueries_cleanup(child);
newfrom = lappend(newfrom, child);
}
f->fromlist = newfrom;
}
else if (IsA(jtnode, JoinExpr))
{
JoinExpr *j = (JoinExpr *) jtnode;
if (j->larg)
j->larg = pull_up_subqueries_cleanup(j->larg);
if (j->rarg)
j->rarg = pull_up_subqueries_cleanup(j->rarg);
if (j->larg == NULL)
{
Assert(j->jointype == JOIN_INNER);
Assert(j->rarg != NULL);
return (Node *) makeFromExpr(list_make1(j->rarg), j->quals);
}
else if (j->rarg == NULL)
{
Assert(j->jointype == JOIN_INNER);
return (Node *) makeFromExpr(list_make1(j->larg), j->quals);
}
}
else
elog(ERROR, "unrecognized node type: %d",
(int) nodeTag(jtnode));
return jtnode;
}
/*
* flatten_simple_union_all
* Try to optimize top-level UNION ALL structure into an appendrel
*
* If a query's setOperations tree consists entirely of simple UNION ALL
* operations, flatten it into an append relation, which we can process more
* intelligently than the general setops case. Otherwise, do nothing.
*
* In most cases, this can succeed only for a top-level query, because for a
* subquery in FROM, the parent query's invocation of pull_up_subqueries would
* already have flattened the UNION via pull_up_simple_union_all. But there
* are a few cases we can support here but not in that code path, for example
* when the subquery also contains ORDER BY.
*/
void
flatten_simple_union_all(PlannerInfo *root)
{
Query *parse = root->parse;
SetOperationStmt *topop;
Node *leftmostjtnode;
int leftmostRTI;
RangeTblEntry *leftmostRTE;
int childRTI;
RangeTblEntry *childRTE;
RangeTblRef *rtr;
/* Shouldn't be called unless query has setops */
topop = castNode(SetOperationStmt, parse->setOperations);
Assert(topop);
/* Can't optimize away a recursive UNION */
if (root->hasRecursion)
return;
/*
* Recursively check the tree of set operations. If not all UNION ALL
* with identical column types, punt.
*/
if (!is_simple_union_all_recurse((Node *) topop, parse, topop->colTypes))
return;
/*
* Locate the leftmost leaf query in the setops tree. The upper query's
* Vars all refer to this RTE (see transformSetOperationStmt).
*/
leftmostjtnode = topop->larg;
while (leftmostjtnode && IsA(leftmostjtnode, SetOperationStmt))
leftmostjtnode = ((SetOperationStmt *) leftmostjtnode)->larg;
Assert(leftmostjtnode && IsA(leftmostjtnode, RangeTblRef));
leftmostRTI = ((RangeTblRef *) leftmostjtnode)->rtindex;
leftmostRTE = rt_fetch(leftmostRTI, parse->rtable);
Assert(leftmostRTE->rtekind == RTE_SUBQUERY);
/*
* Make a copy of the leftmost RTE and add it to the rtable. This copy
* will represent the leftmost leaf query in its capacity as a member of
* the appendrel. The original will represent the appendrel as a whole.
* (We must do things this way because the upper query's Vars have to be
* seen as referring to the whole appendrel.)
*/
childRTE = copyObject(leftmostRTE);
parse->rtable = lappend(parse->rtable, childRTE);
childRTI = list_length(parse->rtable);
/* Modify the setops tree to reference the child copy */
((RangeTblRef *) leftmostjtnode)->rtindex = childRTI;
/* Modify the formerly-leftmost RTE to mark it as an appendrel parent */
leftmostRTE->inh = true;
/*
* Form a RangeTblRef for the appendrel, and insert it into FROM. The top
* Query of a setops tree should have had an empty FromClause initially.
*/
rtr = makeNode(RangeTblRef);
rtr->rtindex = leftmostRTI;
Assert(parse->jointree->fromlist == NIL);
parse->jointree->fromlist = list_make1(rtr);
/*
* Now pretend the query has no setops. We must do this before trying to
* do subquery pullup, because of Assert in pull_up_simple_subquery.
*/
parse->setOperations = NULL;
/*
* Build AppendRelInfo information, and apply pull_up_subqueries to the
* leaf queries of the UNION ALL. (We must do that now because they
* weren't previously referenced by the jointree, and so were missed by
* the main invocation of pull_up_subqueries.)
*/
pull_up_union_leaf_queries((Node *) topop, root, leftmostRTI, parse, 0);
}
/*
* reduce_outer_joins
* Attempt to reduce outer joins to plain inner joins.
*
* The idea here is that given a query like
* SELECT ... FROM a LEFT JOIN b ON (...) WHERE b.y = 42;
* we can reduce the LEFT JOIN to a plain JOIN if the "=" operator in WHERE
* is strict. The strict operator will always return NULL, causing the outer
* WHERE to fail, on any row where the LEFT JOIN filled in NULLs for b's
* columns. Therefore, there's no need for the join to produce null-extended
* rows in the first place --- which makes it a plain join not an outer join.
* (This scenario may not be very likely in a query written out by hand, but
* it's reasonably likely when pushing quals down into complex views.)
*
* More generally, an outer join can be reduced in strength if there is a
* strict qual above it in the qual tree that constrains a Var from the
* nullable side of the join to be non-null. (For FULL joins this applies
* to each side separately.)
*
* Another transformation we apply here is to recognize cases like
* SELECT ... FROM a LEFT JOIN b ON (a.x = b.y) WHERE b.y IS NULL;
* If the join clause is strict for b.y, then only null-extended rows could
* pass the upper WHERE, and we can conclude that what the query is really
* specifying is an anti-semijoin. We change the join type from JOIN_LEFT
* to JOIN_ANTI. The IS NULL clause then becomes redundant, and must be
* removed to prevent bogus selectivity calculations, but we leave it to
* distribute_qual_to_rels to get rid of such clauses.
*
* Also, we get rid of JOIN_RIGHT cases by flipping them around to become
* JOIN_LEFT. This saves some code here and in some later planner routines,
* but the main reason to do it is to not need to invent a JOIN_REVERSE_ANTI
* join type.
*
* To ease recognition of strict qual clauses, we require this routine to be
* run after expression preprocessing (i.e., qual canonicalization and JOIN
* alias-var expansion).
*/
void
reduce_outer_joins(PlannerInfo *root)
{
reduce_outer_joins_state *state;
/*
* To avoid doing strictness checks on more quals than necessary, we want
* to stop descending the jointree as soon as there are no outer joins
* below our current point. This consideration forces a two-pass process.
* The first pass gathers information about which base rels appear below
* each side of each join clause, and about whether there are outer
* join(s) below each side of each join clause. The second pass examines
* qual clauses and changes join types as it descends the tree.
*/
state = reduce_outer_joins_pass1((Node *) root->parse->jointree);
/* planner.c shouldn't have called me if no outer joins */
if (state == NULL || !state->contains_outer)
elog(ERROR, "so where are the outer joins?");
reduce_outer_joins_pass2((Node *) root->parse->jointree,
state, root, NULL, NIL, NIL);
}
/*
* reduce_outer_joins_pass1 - phase 1 data collection
*
* Returns a state node describing the given jointree node.
*/
static reduce_outer_joins_state *
reduce_outer_joins_pass1(Node *jtnode)
{
reduce_outer_joins_state *result;
result = (reduce_outer_joins_state *)
palloc(sizeof(reduce_outer_joins_state));
result->relids = NULL;
result->contains_outer = false;
result->sub_states = NIL;
if (jtnode == NULL)
return result;
if (IsA(jtnode, RangeTblRef))
{
int varno = ((RangeTblRef *) jtnode)->rtindex;
result->relids = bms_make_singleton(varno);
}
else if (IsA(jtnode, FromExpr))
{
FromExpr *f = (FromExpr *) jtnode;
ListCell *l;
foreach(l, f->fromlist)
{
reduce_outer_joins_state *sub_state;
sub_state = reduce_outer_joins_pass1(lfirst(l));
result->relids = bms_add_members(result->relids,
sub_state->relids);
result->contains_outer |= sub_state->contains_outer;
result->sub_states = lappend(result->sub_states, sub_state);
}
}
else if (IsA(jtnode, JoinExpr))
{
JoinExpr *j = (JoinExpr *) jtnode;
reduce_outer_joins_state *sub_state;
/* join's own RT index is not wanted in result->relids */
if (IS_OUTER_JOIN(j->jointype))
result->contains_outer = true;
sub_state = reduce_outer_joins_pass1(j->larg);
result->relids = bms_add_members(result->relids,
sub_state->relids);
result->contains_outer |= sub_state->contains_outer;
result->sub_states = lappend(result->sub_states, sub_state);
sub_state = reduce_outer_joins_pass1(j->rarg);
result->relids = bms_add_members(result->relids,
sub_state->relids);
result->contains_outer |= sub_state->contains_outer;
result->sub_states = lappend(result->sub_states, sub_state);
}
else
elog(ERROR, "unrecognized node type: %d",
(int) nodeTag(jtnode));
return result;
}
/*
* reduce_outer_joins_pass2 - phase 2 processing
*
* jtnode: current jointree node
* state: state data collected by phase 1 for this node
* root: toplevel planner state
* nonnullable_rels: set of base relids forced non-null by upper quals
* nonnullable_vars: list of Vars forced non-null by upper quals
* forced_null_vars: list of Vars forced null by upper quals
*/
static void
reduce_outer_joins_pass2(Node *jtnode,
reduce_outer_joins_state *state,
PlannerInfo *root,
Relids nonnullable_rels,
List *nonnullable_vars,
List *forced_null_vars)
{
/*
* pass 2 should never descend as far as an empty subnode or base rel,
* because it's only called on subtrees marked as contains_outer.
*/
if (jtnode == NULL)
elog(ERROR, "reached empty jointree");
if (IsA(jtnode, RangeTblRef))
elog(ERROR, "reached base rel");
else if (IsA(jtnode, FromExpr))
{
FromExpr *f = (FromExpr *) jtnode;
ListCell *l;
ListCell *s;
Relids pass_nonnullable_rels;
List *pass_nonnullable_vars;
List *pass_forced_null_vars;
/* Scan quals to see if we can add any constraints */
pass_nonnullable_rels = find_nonnullable_rels(f->quals);
pass_nonnullable_rels = bms_add_members(pass_nonnullable_rels,
nonnullable_rels);
/* NB: we rely on list_concat to not damage its second argument */
pass_nonnullable_vars = find_nonnullable_vars(f->quals);
pass_nonnullable_vars = list_concat(pass_nonnullable_vars,
nonnullable_vars);
pass_forced_null_vars = find_forced_null_vars(f->quals);
pass_forced_null_vars = list_concat(pass_forced_null_vars,
forced_null_vars);
/* And recurse --- but only into interesting subtrees */
Assert(list_length(f->fromlist) == list_length(state->sub_states));
forboth(l, f->fromlist, s, state->sub_states)
{
reduce_outer_joins_state *sub_state = lfirst(s);
if (sub_state->contains_outer)
reduce_outer_joins_pass2(lfirst(l), sub_state, root,
pass_nonnullable_rels,
pass_nonnullable_vars,
pass_forced_null_vars);
}
bms_free(pass_nonnullable_rels);
/* can't so easily clean up var lists, unfortunately */
}
else if (IsA(jtnode, JoinExpr))
{
JoinExpr *j = (JoinExpr *) jtnode;
int rtindex = j->rtindex;
JoinType jointype = j->jointype;
reduce_outer_joins_state *left_state = linitial(state->sub_states);
reduce_outer_joins_state *right_state = lsecond(state->sub_states);
List *local_nonnullable_vars = NIL;
bool computed_local_nonnullable_vars = false;
/* Can we simplify this join? */
switch (jointype)
{
case JOIN_INNER:
break;
case JOIN_LEFT:
if (bms_overlap(nonnullable_rels, right_state->relids))
jointype = JOIN_INNER;
break;
case JOIN_RIGHT:
if (bms_overlap(nonnullable_rels, left_state->relids))
jointype = JOIN_INNER;
break;
case JOIN_FULL:
if (bms_overlap(nonnullable_rels, left_state->relids))
{
if (bms_overlap(nonnullable_rels, right_state->relids))
jointype = JOIN_INNER;
else
jointype = JOIN_LEFT;
}
else
{
if (bms_overlap(nonnullable_rels, right_state->relids))
jointype = JOIN_RIGHT;
}
break;
case JOIN_SEMI:
case JOIN_ANTI:
/*
* These could only have been introduced by pull_up_sublinks,
* so there's no way that upper quals could refer to their
* righthand sides, and no point in checking.
*/
break;
default:
elog(ERROR, "unrecognized join type: %d",
(int) jointype);
break;
}
/*
* Convert JOIN_RIGHT to JOIN_LEFT. Note that in the case where we
* reduced JOIN_FULL to JOIN_RIGHT, this will mean the JoinExpr no
* longer matches the internal ordering of any CoalesceExpr's built to
* represent merged join variables. We don't care about that at
* present, but be wary of it ...
*/
if (jointype == JOIN_RIGHT)
{
Node *tmparg;
tmparg = j->larg;
j->larg = j->rarg;
j->rarg = tmparg;
jointype = JOIN_LEFT;
right_state = linitial(state->sub_states);
left_state = lsecond(state->sub_states);
}
/*
* See if we can reduce JOIN_LEFT to JOIN_ANTI. This is the case if
* the join's own quals are strict for any var that was forced null by
* higher qual levels. NOTE: there are other ways that we could
* detect an anti-join, in particular if we were to check whether Vars
* coming from the RHS must be non-null because of table constraints.
* That seems complicated and expensive though (in particular, one
* would have to be wary of lower outer joins). For the moment this
* seems sufficient.
*/
if (jointype == JOIN_LEFT)
{
List *overlap;
local_nonnullable_vars = find_nonnullable_vars(j->quals);
computed_local_nonnullable_vars = true;
/*
* It's not sufficient to check whether local_nonnullable_vars and
* forced_null_vars overlap: we need to know if the overlap
* includes any RHS variables.
*/
overlap = list_intersection(local_nonnullable_vars,
forced_null_vars);
if (overlap != NIL &&
bms_overlap(pull_varnos((Node *) overlap),
right_state->relids))
jointype = JOIN_ANTI;
}
/* Apply the jointype change, if any, to both jointree node and RTE */
if (rtindex && jointype != j->jointype)
{
RangeTblEntry *rte = rt_fetch(rtindex, root->parse->rtable);
Assert(rte->rtekind == RTE_JOIN);
Assert(rte->jointype == j->jointype);
rte->jointype = jointype;
}
j->jointype = jointype;
/* Only recurse if there's more to do below here */
if (left_state->contains_outer || right_state->contains_outer)
{
Relids local_nonnullable_rels;
List *local_forced_null_vars;
Relids pass_nonnullable_rels;
List *pass_nonnullable_vars;
List *pass_forced_null_vars;
/*
* If this join is (now) inner, we can add any constraints its
* quals provide to those we got from above. But if it is outer,
* we can pass down the local constraints only into the nullable
* side, because an outer join never eliminates any rows from its
* non-nullable side. Also, there is no point in passing upper
* constraints into the nullable side, since if there were any
* we'd have been able to reduce the join. (In the case of upper
* forced-null constraints, we *must not* pass them into the
* nullable side --- they either applied here, or not.) The upshot
* is that we pass either the local or the upper constraints,
* never both, to the children of an outer join.
*
* Note that a SEMI join works like an inner join here: it's okay
* to pass down both local and upper constraints. (There can't be
* any upper constraints affecting its inner side, but it's not
* worth having a separate code path to avoid passing them.)
*
* At a FULL join we just punt and pass nothing down --- is it
* possible to be smarter?
*/
if (jointype != JOIN_FULL)
{
local_nonnullable_rels = find_nonnullable_rels(j->quals);
if (!computed_local_nonnullable_vars)
local_nonnullable_vars = find_nonnullable_vars(j->quals);
local_forced_null_vars = find_forced_null_vars(j->quals);
if (jointype == JOIN_INNER || jointype == JOIN_SEMI)
{
/* OK to merge upper and local constraints */
local_nonnullable_rels = bms_add_members(local_nonnullable_rels,
nonnullable_rels);
local_nonnullable_vars = list_concat(local_nonnullable_vars,
nonnullable_vars);
local_forced_null_vars = list_concat(local_forced_null_vars,
forced_null_vars);
}
}
else
{
/* no use in calculating these */
local_nonnullable_rels = NULL;
local_forced_null_vars = NIL;
}
if (left_state->contains_outer)
{
if (jointype == JOIN_INNER || jointype == JOIN_SEMI)
{
/* pass union of local and upper constraints */
pass_nonnullable_rels = local_nonnullable_rels;
pass_nonnullable_vars = local_nonnullable_vars;
pass_forced_null_vars = local_forced_null_vars;
}
else if (jointype != JOIN_FULL) /* ie, LEFT or ANTI */
{
/* can't pass local constraints to non-nullable side */
pass_nonnullable_rels = nonnullable_rels;
pass_nonnullable_vars = nonnullable_vars;
pass_forced_null_vars = forced_null_vars;
}
else
{
/* no constraints pass through JOIN_FULL */
pass_nonnullable_rels = NULL;
pass_nonnullable_vars = NIL;
pass_forced_null_vars = NIL;
}
reduce_outer_joins_pass2(j->larg, left_state, root,
pass_nonnullable_rels,
pass_nonnullable_vars,
pass_forced_null_vars);
}
if (right_state->contains_outer)
{
if (jointype != JOIN_FULL) /* ie, INNER/LEFT/SEMI/ANTI */
{
/* pass appropriate constraints, per comment above */
pass_nonnullable_rels = local_nonnullable_rels;
pass_nonnullable_vars = local_nonnullable_vars;
pass_forced_null_vars = local_forced_null_vars;
}
else
{
/* no constraints pass through JOIN_FULL */
pass_nonnullable_rels = NULL;
pass_nonnullable_vars = NIL;
pass_forced_null_vars = NIL;
}
reduce_outer_joins_pass2(j->rarg, right_state, root,
pass_nonnullable_rels,
pass_nonnullable_vars,
pass_forced_null_vars);
}
bms_free(local_nonnullable_rels);
}
}
else
elog(ERROR, "unrecognized node type: %d",
(int) nodeTag(jtnode));
}
/*
* substitute_multiple_relids - adjust node relid sets after pulling up
* a subquery
*
* Find any PlaceHolderVar nodes in the given tree that reference the
* pulled-up relid, and change them to reference the replacement relid(s).
*
* NOTE: although this has the form of a walker, we cheat and modify the
* nodes in-place. This should be OK since the tree was copied by
* pullup_replace_vars earlier. Avoid scribbling on the original values of
* the bitmapsets, though, because expression_tree_mutator doesn't copy those.
*/
typedef struct
{
int varno;
int sublevels_up;
Relids subrelids;
} substitute_multiple_relids_context;
static bool
substitute_multiple_relids_walker(Node *node,
substitute_multiple_relids_context *context)
{
if (node == NULL)
return false;
if (IsA(node, PlaceHolderVar))
{
PlaceHolderVar *phv = (PlaceHolderVar *) node;
if (phv->phlevelsup == context->sublevels_up &&
bms_is_member(context->varno, phv->phrels))
{
phv->phrels = bms_union(phv->phrels,
context->subrelids);
phv->phrels = bms_del_member(phv->phrels,
context->varno);
}
/* fall through to examine children */
}
if (IsA(node, Query))
{
/* Recurse into subselects */
bool result;
context->sublevels_up++;
result = query_tree_walker((Query *) node,
substitute_multiple_relids_walker,
(void *) context, 0);
context->sublevels_up--;
return result;
}
/* Shouldn't need to handle planner auxiliary nodes here */
Assert(!IsA(node, SpecialJoinInfo));
Assert(!IsA(node, AppendRelInfo));
Assert(!IsA(node, PlaceHolderInfo));
Assert(!IsA(node, MinMaxAggInfo));
return expression_tree_walker(node, substitute_multiple_relids_walker,
(void *) context);
}
static void
substitute_multiple_relids(Node *node, int varno, Relids subrelids)
{
substitute_multiple_relids_context context;
context.varno = varno;
context.sublevels_up = 0;
context.subrelids = subrelids;
/*
* Must be prepared to start with a Query or a bare expression tree.
*/
query_or_expression_tree_walker(node,
substitute_multiple_relids_walker,
(void *) &context,
0);
}
/*
* fix_append_rel_relids: update RT-index fields of AppendRelInfo nodes
*
* When we pull up a subquery, any AppendRelInfo references to the subquery's
* RT index have to be replaced by the substituted relid (and there had better
* be only one). We also need to apply substitute_multiple_relids to their
* translated_vars lists, since those might contain PlaceHolderVars.
*
* We assume we may modify the AppendRelInfo nodes in-place.
*/
static void
fix_append_rel_relids(List *append_rel_list, int varno, Relids subrelids)
{
ListCell *l;
int subvarno = -1;
/*
* We only want to extract the member relid once, but we mustn't fail
* immediately if there are multiple members; it could be that none of the
* AppendRelInfo nodes refer to it. So compute it on first use. Note that
* bms_singleton_member will complain if set is not singleton.
*/
foreach(l, append_rel_list)
{
AppendRelInfo *appinfo = (AppendRelInfo *) lfirst(l);
/* The parent_relid shouldn't ever be a pullup target */
Assert(appinfo->parent_relid != varno);
if (appinfo->child_relid == varno)
{
if (subvarno < 0)
subvarno = bms_singleton_member(subrelids);
appinfo->child_relid = subvarno;
}
/* Also finish fixups for its translated vars */
substitute_multiple_relids((Node *) appinfo->translated_vars,
varno, subrelids);
}
}
/*
* get_relids_in_jointree: get set of RT indexes present in a jointree
*
* If include_joins is true, join RT indexes are included; if false,
* only base rels are included.
*/
Relids
get_relids_in_jointree(Node *jtnode, bool include_joins)
{
Relids result = NULL;
if (jtnode == NULL)
return result;
if (IsA(jtnode, RangeTblRef))
{
int varno = ((RangeTblRef *) jtnode)->rtindex;
result = bms_make_singleton(varno);
}
else if (IsA(jtnode, FromExpr))
{
FromExpr *f = (FromExpr *) jtnode;
ListCell *l;
foreach(l, f->fromlist)
{
result = bms_join(result,
get_relids_in_jointree(lfirst(l),
include_joins));
}
}
else if (IsA(jtnode, JoinExpr))
{
JoinExpr *j = (JoinExpr *) jtnode;
result = get_relids_in_jointree(j->larg, include_joins);
result = bms_join(result,
get_relids_in_jointree(j->rarg, include_joins));
if (include_joins && j->rtindex)
result = bms_add_member(result, j->rtindex);
}
else
elog(ERROR, "unrecognized node type: %d",
(int) nodeTag(jtnode));
return result;
}
/*
* get_relids_for_join: get set of base RT indexes making up a join
*/
Relids
get_relids_for_join(PlannerInfo *root, int joinrelid)
{
Node *jtnode;
jtnode = find_jointree_node_for_rel((Node *) root->parse->jointree,
joinrelid);
if (!jtnode)
elog(ERROR, "could not find join node %d", joinrelid);
return get_relids_in_jointree(jtnode, false);
}
/*
* find_jointree_node_for_rel: locate jointree node for a base or join RT index
*
* Returns NULL if not found
*/
static Node *
find_jointree_node_for_rel(Node *jtnode, int relid)
{
if (jtnode == NULL)
return NULL;
if (IsA(jtnode, RangeTblRef))
{
int varno = ((RangeTblRef *) jtnode)->rtindex;
if (relid == varno)
return jtnode;
}
else if (IsA(jtnode, FromExpr))
{
FromExpr *f = (FromExpr *) jtnode;
ListCell *l;
foreach(l, f->fromlist)
{
jtnode = find_jointree_node_for_rel(lfirst(l), relid);
if (jtnode)
return jtnode;
}
}
else if (IsA(jtnode, JoinExpr))
{
JoinExpr *j = (JoinExpr *) jtnode;
if (relid == j->rtindex)
return jtnode;
jtnode = find_jointree_node_for_rel(j->larg, relid);
if (jtnode)
return jtnode;
jtnode = find_jointree_node_for_rel(j->rarg, relid);
if (jtnode)
return jtnode;
}
else
elog(ERROR, "unrecognized node type: %d",
(int) nodeTag(jtnode));
return NULL;
}
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