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/*-------------------------------------------------------------------------
*
* joinpath.c
* Routines to find all possible paths for processing a set of joins
*
* Portions Copyright (c) 1996-2022, PostgreSQL Global Development Group
* Portions Copyright (c) 1994, Regents of the University of California
*
*
* IDENTIFICATION
* src/backend/optimizer/path/joinpath.c
*
*-------------------------------------------------------------------------
*/
#include "postgres.h"
#include <math.h>
#include "executor/executor.h"
#include "foreign/fdwapi.h"
#include "nodes/nodeFuncs.h"
#include "optimizer/cost.h"
#include "optimizer/optimizer.h"
#include "optimizer/pathnode.h"
#include "optimizer/paths.h"
#include "optimizer/planmain.h"
#include "optimizer/restrictinfo.h"
#include "utils/typcache.h"
/* Hook for plugins to get control in add_paths_to_joinrel() */
set_join_pathlist_hook_type set_join_pathlist_hook = NULL;
/*
* Paths parameterized by the parent can be considered to be parameterized by
* any of its child.
*/
#define PATH_PARAM_BY_PARENT(path, rel) \
((path)->param_info && bms_overlap(PATH_REQ_OUTER(path), \
(rel)->top_parent_relids))
#define PATH_PARAM_BY_REL_SELF(path, rel) \
((path)->param_info && bms_overlap(PATH_REQ_OUTER(path), (rel)->relids))
#define PATH_PARAM_BY_REL(path, rel) \
(PATH_PARAM_BY_REL_SELF(path, rel) || PATH_PARAM_BY_PARENT(path, rel))
static void try_partial_mergejoin_path(PlannerInfo *root,
RelOptInfo *joinrel,
Path *outer_path,
Path *inner_path,
List *pathkeys,
List *mergeclauses,
List *outersortkeys,
List *innersortkeys,
JoinType jointype,
JoinPathExtraData *extra);
static void sort_inner_and_outer(PlannerInfo *root, RelOptInfo *joinrel,
RelOptInfo *outerrel, RelOptInfo *innerrel,
JoinType jointype, JoinPathExtraData *extra);
static inline bool clause_sides_match_join(RestrictInfo *rinfo,
RelOptInfo *outerrel,
RelOptInfo *innerrel);
static void match_unsorted_outer(PlannerInfo *root, RelOptInfo *joinrel,
RelOptInfo *outerrel, RelOptInfo *innerrel,
JoinType jointype, JoinPathExtraData *extra);
static void consider_parallel_nestloop(PlannerInfo *root,
RelOptInfo *joinrel,
RelOptInfo *outerrel,
RelOptInfo *innerrel,
JoinType jointype,
JoinPathExtraData *extra);
static void consider_parallel_mergejoin(PlannerInfo *root,
RelOptInfo *joinrel,
RelOptInfo *outerrel,
RelOptInfo *innerrel,
JoinType jointype,
JoinPathExtraData *extra,
Path *inner_cheapest_total);
static void hash_inner_and_outer(PlannerInfo *root, RelOptInfo *joinrel,
RelOptInfo *outerrel, RelOptInfo *innerrel,
JoinType jointype, JoinPathExtraData *extra);
static List *select_mergejoin_clauses(PlannerInfo *root,
RelOptInfo *joinrel,
RelOptInfo *outerrel,
RelOptInfo *innerrel,
List *restrictlist,
JoinType jointype,
bool *mergejoin_allowed);
static void generate_mergejoin_paths(PlannerInfo *root,
RelOptInfo *joinrel,
RelOptInfo *innerrel,
Path *outerpath,
JoinType jointype,
JoinPathExtraData *extra,
bool useallclauses,
Path *inner_cheapest_total,
List *merge_pathkeys,
bool is_partial);
/*
* add_paths_to_joinrel
* Given a join relation and two component rels from which it can be made,
* consider all possible paths that use the two component rels as outer
* and inner rel respectively. Add these paths to the join rel's pathlist
* if they survive comparison with other paths (and remove any existing
* paths that are dominated by these paths).
*
* Modifies the pathlist field of the joinrel node to contain the best
* paths found so far.
*
* jointype is not necessarily the same as sjinfo->jointype; it might be
* "flipped around" if we are considering joining the rels in the opposite
* direction from what's indicated in sjinfo.
*
* Also, this routine and others in this module accept the special JoinTypes
* JOIN_UNIQUE_OUTER and JOIN_UNIQUE_INNER to indicate that we should
* unique-ify the outer or inner relation and then apply a regular inner
* join. These values are not allowed to propagate outside this module,
* however. Path cost estimation code may need to recognize that it's
* dealing with such a case --- the combination of nominal jointype INNER
* with sjinfo->jointype == JOIN_SEMI indicates that.
*/
void
add_paths_to_joinrel(PlannerInfo *root,
RelOptInfo *joinrel,
RelOptInfo *outerrel,
RelOptInfo *innerrel,
JoinType jointype,
SpecialJoinInfo *sjinfo,
List *restrictlist)
{
JoinPathExtraData extra;
bool mergejoin_allowed = true;
bool consider_join_pushdown = false;
ListCell *lc;
Relids joinrelids;
/*
* PlannerInfo doesn't contain the SpecialJoinInfos created for joins
* between child relations, even if there is a SpecialJoinInfo node for
* the join between the topmost parents. So, while calculating Relids set
* representing the restriction, consider relids of topmost parent of
* partitions.
*/
if (joinrel->reloptkind == RELOPT_OTHER_JOINREL)
joinrelids = joinrel->top_parent_relids;
else
joinrelids = joinrel->relids;
extra.restrictlist = restrictlist;
extra.mergeclause_list = NIL;
extra.sjinfo = sjinfo;
extra.param_source_rels = NULL;
/*
* See if the inner relation is provably unique for this outer rel.
*
* We have some special cases: for JOIN_SEMI and JOIN_ANTI, it doesn't
* matter since the executor can make the equivalent optimization anyway;
* we need not expend planner cycles on proofs. For JOIN_UNIQUE_INNER, we
* must be considering a semijoin whose inner side is not provably unique
* (else reduce_unique_semijoins would've simplified it), so there's no
* point in calling innerrel_is_unique. However, if the LHS covers all of
* the semijoin's min_lefthand, then it's appropriate to set inner_unique
* because the path produced by create_unique_path will be unique relative
* to the LHS. (If we have an LHS that's only part of the min_lefthand,
* that is *not* true.) For JOIN_UNIQUE_OUTER, pass JOIN_INNER to avoid
* letting that value escape this module.
*/
switch (jointype)
{
case JOIN_SEMI:
case JOIN_ANTI:
/*
* XXX it may be worth proving this to allow a Memoize to be
* considered for Nested Loop Semi/Anti Joins.
*/
extra.inner_unique = false; /* well, unproven */
break;
case JOIN_UNIQUE_INNER:
extra.inner_unique = bms_is_subset(sjinfo->min_lefthand,
outerrel->relids);
break;
case JOIN_UNIQUE_OUTER:
extra.inner_unique = innerrel_is_unique(root,
joinrel->relids,
outerrel->relids,
innerrel,
JOIN_INNER,
restrictlist,
false);
break;
default:
extra.inner_unique = innerrel_is_unique(root,
joinrel->relids,
outerrel->relids,
innerrel,
jointype,
restrictlist,
false);
break;
}
/*
* Find potential mergejoin clauses. We can skip this if we are not
* interested in doing a mergejoin. However, mergejoin may be our only
* way of implementing a full outer join, so override enable_mergejoin if
* it's a full join.
*/
if (enable_mergejoin || jointype == JOIN_FULL)
extra.mergeclause_list = select_mergejoin_clauses(root,
joinrel,
outerrel,
innerrel,
restrictlist,
jointype,
&mergejoin_allowed);
/*
* If it's SEMI, ANTI, or inner_unique join, compute correction factors
* for cost estimation. These will be the same for all paths.
*/
if (jointype == JOIN_SEMI || jointype == JOIN_ANTI || extra.inner_unique)
compute_semi_anti_join_factors(root, joinrel, outerrel, innerrel,
jointype, sjinfo, restrictlist,
&extra.semifactors);
/*
* Decide whether it's sensible to generate parameterized paths for this
* joinrel, and if so, which relations such paths should require. There
* is usually no need to create a parameterized result path unless there
* is a join order restriction that prevents joining one of our input rels
* directly to the parameter source rel instead of joining to the other
* input rel. (But see allow_star_schema_join().) This restriction
* reduces the number of parameterized paths we have to deal with at
* higher join levels, without compromising the quality of the resulting
* plan. We express the restriction as a Relids set that must overlap the
* parameterization of any proposed join path.
*/
foreach(lc, root->join_info_list)
{
SpecialJoinInfo *sjinfo2 = (SpecialJoinInfo *) lfirst(lc);
/*
* SJ is relevant to this join if we have some part of its RHS
* (possibly not all of it), and haven't yet joined to its LHS. (This
* test is pretty simplistic, but should be sufficient considering the
* join has already been proven legal.) If the SJ is relevant, it
* presents constraints for joining to anything not in its RHS.
*/
if (bms_overlap(joinrelids, sjinfo2->min_righthand) &&
!bms_overlap(joinrelids, sjinfo2->min_lefthand))
extra.param_source_rels = bms_join(extra.param_source_rels,
bms_difference(root->all_baserels,
sjinfo2->min_righthand));
/* full joins constrain both sides symmetrically */
if (sjinfo2->jointype == JOIN_FULL &&
bms_overlap(joinrelids, sjinfo2->min_lefthand) &&
!bms_overlap(joinrelids, sjinfo2->min_righthand))
extra.param_source_rels = bms_join(extra.param_source_rels,
bms_difference(root->all_baserels,
sjinfo2->min_lefthand));
}
/*
* However, when a LATERAL subquery is involved, there will simply not be
* any paths for the joinrel that aren't parameterized by whatever the
* subquery is parameterized by, unless its parameterization is resolved
* within the joinrel. So we might as well allow additional dependencies
* on whatever residual lateral dependencies the joinrel will have.
*/
extra.param_source_rels = bms_add_members(extra.param_source_rels,
joinrel->lateral_relids);
/*
* 1. Consider mergejoin paths where both relations must be explicitly
* sorted. Skip this if we can't mergejoin.
*/
if (mergejoin_allowed)
sort_inner_and_outer(root, joinrel, outerrel, innerrel,
jointype, &extra);
/*
* 2. Consider paths where the outer relation need not be explicitly
* sorted. This includes both nestloops and mergejoins where the outer
* path is already ordered. Again, skip this if we can't mergejoin.
* (That's okay because we know that nestloop can't handle right/full
* joins at all, so it wouldn't work in the prohibited cases either.)
*/
if (mergejoin_allowed)
match_unsorted_outer(root, joinrel, outerrel, innerrel,
jointype, &extra);
#ifdef NOT_USED
/*
* 3. Consider paths where the inner relation need not be explicitly
* sorted. This includes mergejoins only (nestloops were already built in
* match_unsorted_outer).
*
* Diked out as redundant 2/13/2000 -- tgl. There isn't any really
* significant difference between the inner and outer side of a mergejoin,
* so match_unsorted_inner creates no paths that aren't equivalent to
* those made by match_unsorted_outer when add_paths_to_joinrel() is
* invoked with the two rels given in the other order.
*/
if (mergejoin_allowed)
match_unsorted_inner(root, joinrel, outerrel, innerrel,
jointype, &extra);
#endif
/*
* 4. Consider paths where both outer and inner relations must be hashed
* before being joined. As above, disregard enable_hashjoin for full
* joins, because there may be no other alternative.
*/
if (enable_hashjoin || jointype == JOIN_FULL)
hash_inner_and_outer(root, joinrel, outerrel, innerrel,
jointype, &extra);
/*
* createplan.c does not currently support handling of pseudoconstant
* clauses assigned to joins pushed down by extensions; check if the
* restrictlist has such clauses, and if not, allow them to consider
* pushing down joins.
*/
if ((joinrel->fdwroutine &&
joinrel->fdwroutine->GetForeignJoinPaths) ||
set_join_pathlist_hook)
consider_join_pushdown = !has_pseudoconstant_clauses(root,
restrictlist);
/*
* 5. If inner and outer relations are foreign tables (or joins) belonging
* to the same server and assigned to the same user to check access
* permissions as, give the FDW a chance to push down joins.
*/
if (joinrel->fdwroutine &&
joinrel->fdwroutine->GetForeignJoinPaths &&
consider_join_pushdown)
joinrel->fdwroutine->GetForeignJoinPaths(root, joinrel,
outerrel, innerrel,
jointype, &extra);
/*
* 6. Finally, give extensions a chance to manipulate the path list. They
* could add new paths (such as CustomPaths) by calling add_path(), or
* add_partial_path() if parallel aware. They could also delete or modify
* paths added by the core code.
*/
if (set_join_pathlist_hook &&
consider_join_pushdown)
set_join_pathlist_hook(root, joinrel, outerrel, innerrel,
jointype, &extra);
}
/*
* We override the param_source_rels heuristic to accept nestloop paths in
* which the outer rel satisfies some but not all of the inner path's
* parameterization. This is necessary to get good plans for star-schema
* scenarios, in which a parameterized path for a large table may require
* parameters from multiple small tables that will not get joined directly to
* each other. We can handle that by stacking nestloops that have the small
* tables on the outside; but this breaks the rule the param_source_rels
* heuristic is based on, namely that parameters should not be passed down
* across joins unless there's a join-order-constraint-based reason to do so.
* So we ignore the param_source_rels restriction when this case applies.
*
* allow_star_schema_join() returns true if the param_source_rels restriction
* should be overridden, ie, it's okay to perform this join.
*/
static inline bool
allow_star_schema_join(PlannerInfo *root,
Relids outerrelids,
Relids inner_paramrels)
{
/*
* It's a star-schema case if the outer rel provides some but not all of
* the inner rel's parameterization.
*/
return (bms_overlap(inner_paramrels, outerrelids) &&
bms_nonempty_difference(inner_paramrels, outerrelids));
}
/*
* paraminfo_get_equal_hashops
* Determine if param_info and innerrel's lateral_vars can be hashed.
* Returns true the hashing is possible, otherwise return false.
*
* Additionally we also collect the outer exprs and the hash operators for
* each parameter to innerrel. These set in 'param_exprs', 'operators' and
* 'binary_mode' when we return true.
*/
static bool
paraminfo_get_equal_hashops(PlannerInfo *root, ParamPathInfo *param_info,
RelOptInfo *outerrel, RelOptInfo *innerrel,
List **param_exprs, List **operators,
bool *binary_mode)
{
ListCell *lc;
*param_exprs = NIL;
*operators = NIL;
*binary_mode = false;
if (param_info != NULL)
{
List *clauses = param_info->ppi_clauses;
foreach(lc, clauses)
{
RestrictInfo *rinfo = (RestrictInfo *) lfirst(lc);
OpExpr *opexpr;
Node *expr;
Oid hasheqoperator;
opexpr = (OpExpr *) rinfo->clause;
/*
* Bail if the rinfo is not compatible. We need a join OpExpr
* with 2 args.
*/
if (!IsA(opexpr, OpExpr) || list_length(opexpr->args) != 2 ||
!clause_sides_match_join(rinfo, outerrel, innerrel))
{
list_free(*operators);
list_free(*param_exprs);
return false;
}
if (rinfo->outer_is_left)
{
expr = (Node *) linitial(opexpr->args);
hasheqoperator = rinfo->left_hasheqoperator;
}
else
{
expr = (Node *) lsecond(opexpr->args);
hasheqoperator = rinfo->right_hasheqoperator;
}
/* can't do memoize if we can't hash the outer type */
if (!OidIsValid(hasheqoperator))
{
list_free(*operators);
list_free(*param_exprs);
return false;
}
*operators = lappend_oid(*operators, hasheqoperator);
*param_exprs = lappend(*param_exprs, expr);
/*
* When the join operator is not hashable then it's possible that
* the operator will be able to distinguish something that the
* hash equality operator could not. For example with floating
* point types -0.0 and +0.0 are classed as equal by the hash
* function and equality function, but some other operator may be
* able to tell those values apart. This means that we must put
* memoize into binary comparison mode so that it does bit-by-bit
* comparisons rather than a "logical" comparison as it would
* using the hash equality operator.
*/
if (!OidIsValid(rinfo->hashjoinoperator))
*binary_mode = true;
}
}
/* Now add any lateral vars to the cache key too */
foreach(lc, innerrel->lateral_vars)
{
Node *expr = (Node *) lfirst(lc);
TypeCacheEntry *typentry;
/* Reject if there are any volatile functions */
if (contain_volatile_functions(expr))
{
list_free(*operators);
list_free(*param_exprs);
return false;
}
typentry = lookup_type_cache(exprType(expr),
TYPECACHE_HASH_PROC | TYPECACHE_EQ_OPR);
/* can't use a memoize node without a valid hash equals operator */
if (!OidIsValid(typentry->hash_proc) || !OidIsValid(typentry->eq_opr))
{
list_free(*operators);
list_free(*param_exprs);
return false;
}
*operators = lappend_oid(*operators, typentry->eq_opr);
*param_exprs = lappend(*param_exprs, expr);
/*
* We must go into binary mode as we don't have too much of an idea of
* how these lateral Vars are being used. See comment above when we
* set *binary_mode for the non-lateral Var case. This could be
* relaxed a bit if we had the RestrictInfos and knew the operators
* being used, however for cases like Vars that are arguments to
* functions we must operate in binary mode as we don't have
* visibility into what the function is doing with the Vars.
*/
*binary_mode = true;
}
/* We're okay to use memoize */
return true;
}
/*
* get_memoize_path
* If possible, make and return a Memoize path atop of 'inner_path'.
* Otherwise return NULL.
*/
static Path *
get_memoize_path(PlannerInfo *root, RelOptInfo *innerrel,
RelOptInfo *outerrel, Path *inner_path,
Path *outer_path, JoinType jointype,
JoinPathExtraData *extra)
{
RelOptInfo *top_outerrel;
List *param_exprs;
List *hash_operators;
ListCell *lc;
bool binary_mode;
/* Obviously not if it's disabled */
if (!enable_memoize)
return NULL;
/*
* We can safely not bother with all this unless we expect to perform more
* than one inner scan. The first scan is always going to be a cache
* miss. This would likely fail later anyway based on costs, so this is
* really just to save some wasted effort.
*/
if (outer_path->parent->rows < 2)
return NULL;
/*
* We can only have a memoize node when there's some kind of cache key,
* either parameterized path clauses or lateral Vars. No cache key sounds
* more like something a Materialize node might be more useful for.
*/
if ((inner_path->param_info == NULL ||
inner_path->param_info->ppi_clauses == NIL) &&
innerrel->lateral_vars == NIL)
return NULL;
/*
* Currently we don't do this for SEMI and ANTI joins unless they're
* marked as inner_unique. This is because nested loop SEMI/ANTI joins
* don't scan the inner node to completion, which will mean memoize cannot
* mark the cache entry as complete.
*
* XXX Currently we don't attempt to mark SEMI/ANTI joins as inner_unique
* = true. Should we? See add_paths_to_joinrel()
*/
if (!extra->inner_unique && (jointype == JOIN_SEMI ||
jointype == JOIN_ANTI))
return NULL;
/*
* Memoize normally marks cache entries as complete when it runs out of
* tuples to read from its subplan. However, with unique joins, Nested
* Loop will skip to the next outer tuple after finding the first matching
* inner tuple. This means that we may not read the inner side of the
* join to completion which leaves no opportunity to mark the cache entry
* as complete. To work around that, when the join is unique we
* automatically mark cache entries as complete after fetching the first
* tuple. This works when the entire join condition is parameterized.
* Otherwise, when the parameterization is only a subset of the join
* condition, we can't be sure which part of it causes the join to be
* unique. This means there are no guarantees that only 1 tuple will be
* read. We cannot mark the cache entry as complete after reading the
* first tuple without that guarantee. This means the scope of Memoize
* node's usefulness is limited to only outer rows that have no join
* partner as this is the only case where Nested Loop would exhaust the
* inner scan of a unique join. Since the scope is limited to that, we
* just don't bother making a memoize path in this case.
*
* Lateral vars needn't be considered here as they're not considered when
* determining if the join is unique.
*
* XXX this could be enabled if the remaining join quals were made part of
* the inner scan's filter instead of the join filter. Maybe it's worth
* considering doing that?
*/
if (extra->inner_unique &&
(inner_path->param_info == NULL ||
list_length(inner_path->param_info->ppi_clauses) <
list_length(extra->restrictlist)))
return NULL;
/*
* We can't use a memoize node if there are volatile functions in the
* inner rel's target list or restrict list. A cache hit could reduce the
* number of calls to these functions.
*/
if (contain_volatile_functions((Node *) innerrel->reltarget))
return NULL;
foreach(lc, innerrel->baserestrictinfo)
{
RestrictInfo *rinfo = (RestrictInfo *) lfirst(lc);
if (contain_volatile_functions((Node *) rinfo))
return NULL;
}
/*
* Also check the parameterized path restrictinfos for volatile functions.
* Indexed functions must be immutable so shouldn't have any volatile
* functions, however, with a lateral join the inner scan may not be an
* index scan.
*/
if (inner_path->param_info != NULL)
{
foreach(lc, inner_path->param_info->ppi_clauses)
{
RestrictInfo *rinfo = (RestrictInfo *) lfirst(lc);
if (contain_volatile_functions((Node *) rinfo))
return NULL;
}
}
/*
* When considering a partitionwise join, we have clauses that reference
* the outerrel's top parent not outerrel itself.
*/
if (outerrel->reloptkind == RELOPT_OTHER_MEMBER_REL)
top_outerrel = find_base_rel(root, bms_singleton_member(outerrel->top_parent_relids));
else if (outerrel->reloptkind == RELOPT_OTHER_JOINREL)
top_outerrel = find_join_rel(root, outerrel->top_parent_relids);
else
top_outerrel = outerrel;
/* Check if we have hash ops for each parameter to the path */
if (paraminfo_get_equal_hashops(root,
inner_path->param_info,
top_outerrel,
innerrel,
¶m_exprs,
&hash_operators,
&binary_mode))
{
return (Path *) create_memoize_path(root,
innerrel,
inner_path,
param_exprs,
hash_operators,
extra->inner_unique,
binary_mode,
outer_path->rows);
}
return NULL;
}
/*
* try_nestloop_path
* Consider a nestloop join path; if it appears useful, push it into
* the joinrel's pathlist via add_path().
*/
static void
try_nestloop_path(PlannerInfo *root,
RelOptInfo *joinrel,
Path *outer_path,
Path *inner_path,
List *pathkeys,
JoinType jointype,
JoinPathExtraData *extra)
{
Relids required_outer;
JoinCostWorkspace workspace;
RelOptInfo *innerrel = inner_path->parent;
RelOptInfo *outerrel = outer_path->parent;
Relids innerrelids;
Relids outerrelids;
Relids inner_paramrels = PATH_REQ_OUTER(inner_path);
Relids outer_paramrels = PATH_REQ_OUTER(outer_path);
/*
* Paths are parameterized by top-level parents, so run parameterization
* tests on the parent relids.
*/
if (innerrel->top_parent_relids)
innerrelids = innerrel->top_parent_relids;
else
innerrelids = innerrel->relids;
if (outerrel->top_parent_relids)
outerrelids = outerrel->top_parent_relids;
else
outerrelids = outerrel->relids;
/*
* Check to see if proposed path is still parameterized, and reject if the
* parameterization wouldn't be sensible --- unless allow_star_schema_join
* says to allow it anyway. Also, we must reject if have_dangerous_phv
* doesn't like the look of it, which could only happen if the nestloop is
* still parameterized.
*/
required_outer = calc_nestloop_required_outer(outerrelids, outer_paramrels,
innerrelids, inner_paramrels);
if (required_outer &&
((!bms_overlap(required_outer, extra->param_source_rels) &&
!allow_star_schema_join(root, outerrelids, inner_paramrels)) ||
have_dangerous_phv(root, outerrelids, inner_paramrels)))
{
/* Waste no memory when we reject a path here */
bms_free(required_outer);
return;
}
/*
* Do a precheck to quickly eliminate obviously-inferior paths. We
* calculate a cheap lower bound on the path's cost and then use
* add_path_precheck() to see if the path is clearly going to be dominated
* by some existing path for the joinrel. If not, do the full pushup with
* creating a fully valid path structure and submitting it to add_path().
* The latter two steps are expensive enough to make this two-phase
* methodology worthwhile.
*/
initial_cost_nestloop(root, &workspace, jointype,
outer_path, inner_path, extra);
if (add_path_precheck(joinrel,
workspace.startup_cost, workspace.total_cost,
pathkeys, required_outer))
{
/*
* If the inner path is parameterized, it is parameterized by the
* topmost parent of the outer rel, not the outer rel itself. Fix
* that.
*/
if (PATH_PARAM_BY_PARENT(inner_path, outer_path->parent))
{
inner_path = reparameterize_path_by_child(root, inner_path,
outer_path->parent);
/*
* If we could not translate the path, we can't create nest loop
* path.
*/
if (!inner_path)
{
bms_free(required_outer);
return;
}
}
add_path(joinrel, (Path *)
create_nestloop_path(root,
joinrel,
jointype,
&workspace,
extra,
outer_path,
inner_path,
extra->restrictlist,
pathkeys,
required_outer));
}
else
{
/* Waste no memory when we reject a path here */
bms_free(required_outer);
}
}
/*
* try_partial_nestloop_path
* Consider a partial nestloop join path; if it appears useful, push it into
* the joinrel's partial_pathlist via add_partial_path().
*/
static void
try_partial_nestloop_path(PlannerInfo *root,
RelOptInfo *joinrel,
Path *outer_path,
Path *inner_path,
List *pathkeys,
JoinType jointype,
JoinPathExtraData *extra)
{
JoinCostWorkspace workspace;
/*
* If the inner path is parameterized, the parameterization must be fully
* satisfied by the proposed outer path. Parameterized partial paths are
* not supported. The caller should already have verified that no lateral
* rels are required here.
*/
Assert(bms_is_empty(joinrel->lateral_relids));
if (inner_path->param_info != NULL)
{
Relids inner_paramrels = inner_path->param_info->ppi_req_outer;
RelOptInfo *outerrel = outer_path->parent;
Relids outerrelids;
/*
* The inner and outer paths are parameterized, if at all, by the top
* level parents, not the child relations, so we must use those relids
* for our parameterization tests.
*/
if (outerrel->top_parent_relids)
outerrelids = outerrel->top_parent_relids;
else
outerrelids = outerrel->relids;
if (!bms_is_subset(inner_paramrels, outerrelids))
return;
}
/*
* Before creating a path, get a quick lower bound on what it is likely to
* cost. Bail out right away if it looks terrible.
*/
initial_cost_nestloop(root, &workspace, jointype,
outer_path, inner_path, extra);
if (!add_partial_path_precheck(joinrel, workspace.total_cost, pathkeys))
return;
/*
* If the inner path is parameterized, it is parameterized by the topmost
* parent of the outer rel, not the outer rel itself. Fix that.
*/
if (PATH_PARAM_BY_PARENT(inner_path, outer_path->parent))
{
inner_path = reparameterize_path_by_child(root, inner_path,
outer_path->parent);
/*
* If we could not translate the path, we can't create nest loop path.
*/
if (!inner_path)
return;
}
/* Might be good enough to be worth trying, so let's try it. */
add_partial_path(joinrel, (Path *)
create_nestloop_path(root,
joinrel,
jointype,
&workspace,
extra,
outer_path,
inner_path,
extra->restrictlist,
pathkeys,
NULL));
}
/*
* try_mergejoin_path
* Consider a merge join path; if it appears useful, push it into
* the joinrel's pathlist via add_path().
*/
static void
try_mergejoin_path(PlannerInfo *root,
RelOptInfo *joinrel,
Path *outer_path,
Path *inner_path,
List *pathkeys,
List *mergeclauses,
List *outersortkeys,
List *innersortkeys,
JoinType jointype,
JoinPathExtraData *extra,
bool is_partial)
{
Relids required_outer;
JoinCostWorkspace workspace;
if (is_partial)
{
try_partial_mergejoin_path(root,
joinrel,
outer_path,
inner_path,
pathkeys,
mergeclauses,
outersortkeys,
innersortkeys,
jointype,
extra);
return;
}
/*
* Check to see if proposed path is still parameterized, and reject if the
* parameterization wouldn't be sensible.
*/
required_outer = calc_non_nestloop_required_outer(outer_path,
inner_path);
if (required_outer &&
!bms_overlap(required_outer, extra->param_source_rels))
{
/* Waste no memory when we reject a path here */
bms_free(required_outer);
return;
}
/*
* If the given paths are already well enough ordered, we can skip doing
* an explicit sort.
*/
if (outersortkeys &&
pathkeys_contained_in(outersortkeys, outer_path->pathkeys))
outersortkeys = NIL;
if (innersortkeys &&
pathkeys_contained_in(innersortkeys, inner_path->pathkeys))
innersortkeys = NIL;
/*
* See comments in try_nestloop_path().
*/
initial_cost_mergejoin(root, &workspace, jointype, mergeclauses,
outer_path, inner_path,
outersortkeys, innersortkeys,
extra);
if (add_path_precheck(joinrel,
workspace.startup_cost, workspace.total_cost,
pathkeys, required_outer))
{
add_path(joinrel, (Path *)
create_mergejoin_path(root,
joinrel,
jointype,
&workspace,
extra,
outer_path,
inner_path,
extra->restrictlist,
pathkeys,
required_outer,
mergeclauses,
outersortkeys,
innersortkeys));
}
else
{
/* Waste no memory when we reject a path here */
bms_free(required_outer);
}
}
/*
* try_partial_mergejoin_path
* Consider a partial merge join path; if it appears useful, push it into
* the joinrel's pathlist via add_partial_path().
*/
static void
try_partial_mergejoin_path(PlannerInfo *root,
RelOptInfo *joinrel,
Path *outer_path,
Path *inner_path,
List *pathkeys,
List *mergeclauses,
List *outersortkeys,
List *innersortkeys,
JoinType jointype,
JoinPathExtraData *extra)
{
JoinCostWorkspace workspace;
/*
* See comments in try_partial_hashjoin_path().
*/
Assert(bms_is_empty(joinrel->lateral_relids));
if (inner_path->param_info != NULL)
{
Relids inner_paramrels = inner_path->param_info->ppi_req_outer;
if (!bms_is_empty(inner_paramrels))
return;
}
/*
* If the given paths are already well enough ordered, we can skip doing
* an explicit sort.
*/
if (outersortkeys &&
pathkeys_contained_in(outersortkeys, outer_path->pathkeys))
outersortkeys = NIL;
if (innersortkeys &&
pathkeys_contained_in(innersortkeys, inner_path->pathkeys))
innersortkeys = NIL;
/*
* See comments in try_partial_nestloop_path().
*/
initial_cost_mergejoin(root, &workspace, jointype, mergeclauses,
outer_path, inner_path,
outersortkeys, innersortkeys,
extra);
if (!add_partial_path_precheck(joinrel, workspace.total_cost, pathkeys))
return;
/* Might be good enough to be worth trying, so let's try it. */
add_partial_path(joinrel, (Path *)
create_mergejoin_path(root,
joinrel,
jointype,
&workspace,
extra,
outer_path,
inner_path,
extra->restrictlist,
pathkeys,
NULL,
mergeclauses,
outersortkeys,
innersortkeys));
}
/*
* try_hashjoin_path
* Consider a hash join path; if it appears useful, push it into
* the joinrel's pathlist via add_path().
*/
static void
try_hashjoin_path(PlannerInfo *root,
RelOptInfo *joinrel,
Path *outer_path,
Path *inner_path,
List *hashclauses,
JoinType jointype,
JoinPathExtraData *extra)
{
Relids required_outer;
JoinCostWorkspace workspace;
/*
* Check to see if proposed path is still parameterized, and reject if the
* parameterization wouldn't be sensible.
*/
required_outer = calc_non_nestloop_required_outer(outer_path,
inner_path);
if (required_outer &&
!bms_overlap(required_outer, extra->param_source_rels))
{
/* Waste no memory when we reject a path here */
bms_free(required_outer);
return;
}
/*
* See comments in try_nestloop_path(). Also note that hashjoin paths
* never have any output pathkeys, per comments in create_hashjoin_path.
*/
initial_cost_hashjoin(root, &workspace, jointype, hashclauses,
outer_path, inner_path, extra, false);
if (add_path_precheck(joinrel,
workspace.startup_cost, workspace.total_cost,
NIL, required_outer))
{
add_path(joinrel, (Path *)
create_hashjoin_path(root,
joinrel,
jointype,
&workspace,
extra,
outer_path,
inner_path,
false, /* parallel_hash */
extra->restrictlist,
required_outer,
hashclauses));
}
else
{
/* Waste no memory when we reject a path here */
bms_free(required_outer);
}
}
/*
* try_partial_hashjoin_path
* Consider a partial hashjoin join path; if it appears useful, push it into
* the joinrel's partial_pathlist via add_partial_path().
* The outer side is partial. If parallel_hash is true, then the inner path
* must be partial and will be run in parallel to create one or more shared
* hash tables; otherwise the inner path must be complete and a copy of it
* is run in every process to create separate identical private hash tables.
*/
static void
try_partial_hashjoin_path(PlannerInfo *root,
RelOptInfo *joinrel,
Path *outer_path,
Path *inner_path,
List *hashclauses,
JoinType jointype,
JoinPathExtraData *extra,
bool parallel_hash)
{
JoinCostWorkspace workspace;
/*
* If the inner path is parameterized, the parameterization must be fully
* satisfied by the proposed outer path. Parameterized partial paths are
* not supported. The caller should already have verified that no lateral
* rels are required here.
*/
Assert(bms_is_empty(joinrel->lateral_relids));
if (inner_path->param_info != NULL)
{
Relids inner_paramrels = inner_path->param_info->ppi_req_outer;
if (!bms_is_empty(inner_paramrels))
return;
}
/*
* Before creating a path, get a quick lower bound on what it is likely to
* cost. Bail out right away if it looks terrible.
*/
initial_cost_hashjoin(root, &workspace, jointype, hashclauses,
outer_path, inner_path, extra, parallel_hash);
if (!add_partial_path_precheck(joinrel, workspace.total_cost, NIL))
return;
/* Might be good enough to be worth trying, so let's try it. */
add_partial_path(joinrel, (Path *)
create_hashjoin_path(root,
joinrel,
jointype,
&workspace,
extra,
outer_path,
inner_path,
parallel_hash,
extra->restrictlist,
NULL,
hashclauses));
}
/*
* clause_sides_match_join
* Determine whether a join clause is of the right form to use in this join.
*
* We already know that the clause is a binary opclause referencing only the
* rels in the current join. The point here is to check whether it has the
* form "outerrel_expr op innerrel_expr" or "innerrel_expr op outerrel_expr",
* rather than mixing outer and inner vars on either side. If it matches,
* we set the transient flag outer_is_left to identify which side is which.
*/
static inline bool
clause_sides_match_join(RestrictInfo *rinfo, RelOptInfo *outerrel,
RelOptInfo *innerrel)
{
if (bms_is_subset(rinfo->left_relids, outerrel->relids) &&
bms_is_subset(rinfo->right_relids, innerrel->relids))
{
/* lefthand side is outer */
rinfo->outer_is_left = true;
return true;
}
else if (bms_is_subset(rinfo->left_relids, innerrel->relids) &&
bms_is_subset(rinfo->right_relids, outerrel->relids))
{
/* righthand side is outer */
rinfo->outer_is_left = false;
return true;
}
return false; /* no good for these input relations */
}
/*
* sort_inner_and_outer
* Create mergejoin join paths by explicitly sorting both the outer and
* inner join relations on each available merge ordering.
*
* 'joinrel' is the join relation
* 'outerrel' is the outer join relation
* 'innerrel' is the inner join relation
* 'jointype' is the type of join to do
* 'extra' contains additional input values
*/
static void
sort_inner_and_outer(PlannerInfo *root,
RelOptInfo *joinrel,
RelOptInfo *outerrel,
RelOptInfo *innerrel,
JoinType jointype,
JoinPathExtraData *extra)
{
JoinType save_jointype = jointype;
Path *outer_path;
Path *inner_path;
Path *cheapest_partial_outer = NULL;
Path *cheapest_safe_inner = NULL;
List *all_pathkeys;
ListCell *l;
/*
* We only consider the cheapest-total-cost input paths, since we are
* assuming here that a sort is required. We will consider
* cheapest-startup-cost input paths later, and only if they don't need a
* sort.
*
* This function intentionally does not consider parameterized input
* paths, except when the cheapest-total is parameterized. If we did so,
* we'd have a combinatorial explosion of mergejoin paths of dubious
* value. This interacts with decisions elsewhere that also discriminate
* against mergejoins with parameterized inputs; see comments in
* src/backend/optimizer/README.
*/
outer_path = outerrel->cheapest_total_path;
inner_path = innerrel->cheapest_total_path;
/*
* If either cheapest-total path is parameterized by the other rel, we
* can't use a mergejoin. (There's no use looking for alternative input
* paths, since these should already be the least-parameterized available
* paths.)
*/
if (PATH_PARAM_BY_REL(outer_path, innerrel) ||
PATH_PARAM_BY_REL(inner_path, outerrel))
return;
/*
* If unique-ification is requested, do it and then handle as a plain
* inner join.
*/
if (jointype == JOIN_UNIQUE_OUTER)
{
outer_path = (Path *) create_unique_path(root, outerrel,
outer_path, extra->sjinfo);
Assert(outer_path);
jointype = JOIN_INNER;
}
else if (jointype == JOIN_UNIQUE_INNER)
{
inner_path = (Path *) create_unique_path(root, innerrel,
inner_path, extra->sjinfo);
Assert(inner_path);
jointype = JOIN_INNER;
}
/*
* If the joinrel is parallel-safe, we may be able to consider a partial
* merge join. However, we can't handle JOIN_UNIQUE_OUTER, because the
* outer path will be partial, and therefore we won't be able to properly
* guarantee uniqueness. Similarly, we can't handle JOIN_FULL and
* JOIN_RIGHT, because they can produce false null extended rows. Also,
* the resulting path must not be parameterized.
*/
if (joinrel->consider_parallel &&
save_jointype != JOIN_UNIQUE_OUTER &&
save_jointype != JOIN_FULL &&
save_jointype != JOIN_RIGHT &&
outerrel->partial_pathlist != NIL &&
bms_is_empty(joinrel->lateral_relids))
{
cheapest_partial_outer = (Path *) linitial(outerrel->partial_pathlist);
if (inner_path->parallel_safe)
cheapest_safe_inner = inner_path;
else if (save_jointype != JOIN_UNIQUE_INNER)
cheapest_safe_inner =
get_cheapest_parallel_safe_total_inner(innerrel->pathlist);
}
/*
* Each possible ordering of the available mergejoin clauses will generate
* a differently-sorted result path at essentially the same cost. We have
* no basis for choosing one over another at this level of joining, but
* some sort orders may be more useful than others for higher-level
* mergejoins, so it's worth considering multiple orderings.
*
* Actually, it's not quite true that every mergeclause ordering will
* generate a different path order, because some of the clauses may be
* partially redundant (refer to the same EquivalenceClasses). Therefore,
* what we do is convert the mergeclause list to a list of canonical
* pathkeys, and then consider different orderings of the pathkeys.
*
* Generating a path for *every* permutation of the pathkeys doesn't seem
* like a winning strategy; the cost in planning time is too high. For
* now, we generate one path for each pathkey, listing that pathkey first
* and the rest in random order. This should allow at least a one-clause
* mergejoin without re-sorting against any other possible mergejoin
* partner path. But if we've not guessed the right ordering of secondary
* keys, we may end up evaluating clauses as qpquals when they could have
* been done as mergeclauses. (In practice, it's rare that there's more
* than two or three mergeclauses, so expending a huge amount of thought
* on that is probably not worth it.)
*
* The pathkey order returned by select_outer_pathkeys_for_merge() has
* some heuristics behind it (see that function), so be sure to try it
* exactly as-is as well as making variants.
*/
all_pathkeys = select_outer_pathkeys_for_merge(root,
extra->mergeclause_list,
joinrel);
foreach(l, all_pathkeys)
{
PathKey *front_pathkey = (PathKey *) lfirst(l);
List *cur_mergeclauses;
List *outerkeys;
List *innerkeys;
List *merge_pathkeys;
/* Make a pathkey list with this guy first */
if (l != list_head(all_pathkeys))
outerkeys = lcons(front_pathkey,
list_delete_nth_cell(list_copy(all_pathkeys),
foreach_current_index(l)));
else
outerkeys = all_pathkeys; /* no work at first one... */
/* Sort the mergeclauses into the corresponding ordering */
cur_mergeclauses =
find_mergeclauses_for_outer_pathkeys(root,
outerkeys,
extra->mergeclause_list);
/* Should have used them all... */
Assert(list_length(cur_mergeclauses) == list_length(extra->mergeclause_list));
/* Build sort pathkeys for the inner side */
innerkeys = make_inner_pathkeys_for_merge(root,
cur_mergeclauses,
outerkeys);
/* Build pathkeys representing output sort order */
merge_pathkeys = build_join_pathkeys(root, joinrel, jointype,
outerkeys);
/*
* And now we can make the path.
*
* Note: it's possible that the cheapest paths will already be sorted
* properly. try_mergejoin_path will detect that case and suppress an
* explicit sort step, so we needn't do so here.
*/
try_mergejoin_path(root,
joinrel,
outer_path,
inner_path,
merge_pathkeys,
cur_mergeclauses,
outerkeys,
innerkeys,
jointype,
extra,
false);
/*
* If we have partial outer and parallel safe inner path then try
* partial mergejoin path.
*/
if (cheapest_partial_outer && cheapest_safe_inner)
try_partial_mergejoin_path(root,
joinrel,
cheapest_partial_outer,
cheapest_safe_inner,
merge_pathkeys,
cur_mergeclauses,
outerkeys,
innerkeys,
jointype,
extra);
}
}
/*
* generate_mergejoin_paths
* Creates possible mergejoin paths for input outerpath.
*
* We generate mergejoins if mergejoin clauses are available. We have
* two ways to generate the inner path for a mergejoin: sort the cheapest
* inner path, or use an inner path that is already suitably ordered for the
* merge. If we have several mergeclauses, it could be that there is no inner
* path (or only a very expensive one) for the full list of mergeclauses, but
* better paths exist if we truncate the mergeclause list (thereby discarding
* some sort key requirements). So, we consider truncations of the
* mergeclause list as well as the full list. (Ideally we'd consider all
* subsets of the mergeclause list, but that seems way too expensive.)
*/
static void
generate_mergejoin_paths(PlannerInfo *root,
RelOptInfo *joinrel,
RelOptInfo *innerrel,
Path *outerpath,
JoinType jointype,
JoinPathExtraData *extra,
bool useallclauses,
Path *inner_cheapest_total,
List *merge_pathkeys,
bool is_partial)
{
List *mergeclauses;
List *innersortkeys;
List *trialsortkeys;
Path *cheapest_startup_inner;
Path *cheapest_total_inner;
JoinType save_jointype = jointype;
int num_sortkeys;
int sortkeycnt;
if (jointype == JOIN_UNIQUE_OUTER || jointype == JOIN_UNIQUE_INNER)
jointype = JOIN_INNER;
/* Look for useful mergeclauses (if any) */
mergeclauses =
find_mergeclauses_for_outer_pathkeys(root,
outerpath->pathkeys,
extra->mergeclause_list);
/*
* Done with this outer path if no chance for a mergejoin.
*
* Special corner case: for "x FULL JOIN y ON true", there will be no join
* clauses at all. Ordinarily we'd generate a clauseless nestloop path,
* but since mergejoin is our only join type that supports FULL JOIN
* without any join clauses, it's necessary to generate a clauseless
* mergejoin path instead.
*/
if (mergeclauses == NIL)
{
if (jointype == JOIN_FULL)
/* okay to try for mergejoin */ ;
else
return;
}
if (useallclauses &&
list_length(mergeclauses) != list_length(extra->mergeclause_list))
return;
/* Compute the required ordering of the inner path */
innersortkeys = make_inner_pathkeys_for_merge(root,
mergeclauses,
outerpath->pathkeys);
/*
* Generate a mergejoin on the basis of sorting the cheapest inner. Since
* a sort will be needed, only cheapest total cost matters. (But
* try_mergejoin_path will do the right thing if inner_cheapest_total is
* already correctly sorted.)
*/
try_mergejoin_path(root,
joinrel,
outerpath,
inner_cheapest_total,
merge_pathkeys,
mergeclauses,
NIL,
innersortkeys,
jointype,
extra,
is_partial);
/* Can't do anything else if inner path needs to be unique'd */
if (save_jointype == JOIN_UNIQUE_INNER)
return;
/*
* Look for presorted inner paths that satisfy the innersortkey list ---
* or any truncation thereof, if we are allowed to build a mergejoin using
* a subset of the merge clauses. Here, we consider both cheap startup
* cost and cheap total cost.
*
* Currently we do not consider parameterized inner paths here. This
* interacts with decisions elsewhere that also discriminate against
* mergejoins with parameterized inputs; see comments in
* src/backend/optimizer/README.
*
* As we shorten the sortkey list, we should consider only paths that are
* strictly cheaper than (in particular, not the same as) any path found
* in an earlier iteration. Otherwise we'd be intentionally using fewer
* merge keys than a given path allows (treating the rest as plain
* joinquals), which is unlikely to be a good idea. Also, eliminating
* paths here on the basis of compare_path_costs is a lot cheaper than
* building the mergejoin path only to throw it away.
*
* If inner_cheapest_total is well enough sorted to have not required a
* sort in the path made above, we shouldn't make a duplicate path with
* it, either. We handle that case with the same logic that handles the
* previous consideration, by initializing the variables that track
* cheapest-so-far properly. Note that we do NOT reject
* inner_cheapest_total if we find it matches some shorter set of
* pathkeys. That case corresponds to using fewer mergekeys to avoid
* sorting inner_cheapest_total, whereas we did sort it above, so the
* plans being considered are different.
*/
if (pathkeys_contained_in(innersortkeys,
inner_cheapest_total->pathkeys))
{
/* inner_cheapest_total didn't require a sort */
cheapest_startup_inner = inner_cheapest_total;
cheapest_total_inner = inner_cheapest_total;
}
else
{
/* it did require a sort, at least for the full set of keys */
cheapest_startup_inner = NULL;
cheapest_total_inner = NULL;
}
num_sortkeys = list_length(innersortkeys);
if (num_sortkeys > 1 && !useallclauses)
trialsortkeys = list_copy(innersortkeys); /* need modifiable copy */
else
trialsortkeys = innersortkeys; /* won't really truncate */
for (sortkeycnt = num_sortkeys; sortkeycnt > 0; sortkeycnt--)
{
Path *innerpath;
List *newclauses = NIL;
/*
* Look for an inner path ordered well enough for the first
* 'sortkeycnt' innersortkeys. NB: trialsortkeys list is modified
* destructively, which is why we made a copy...
*/
trialsortkeys = list_truncate(trialsortkeys, sortkeycnt);
innerpath = get_cheapest_path_for_pathkeys(innerrel->pathlist,
trialsortkeys,
NULL,
TOTAL_COST,
is_partial);
if (innerpath != NULL &&
(cheapest_total_inner == NULL ||
compare_path_costs(innerpath, cheapest_total_inner,
TOTAL_COST) < 0))
{
/* Found a cheap (or even-cheaper) sorted path */
/* Select the right mergeclauses, if we didn't already */
if (sortkeycnt < num_sortkeys)
{
newclauses =
trim_mergeclauses_for_inner_pathkeys(root,
mergeclauses,
trialsortkeys);
Assert(newclauses != NIL);
}
else
newclauses = mergeclauses;
try_mergejoin_path(root,
joinrel,
outerpath,
innerpath,
merge_pathkeys,
newclauses,
NIL,
NIL,
jointype,
extra,
is_partial);
cheapest_total_inner = innerpath;
}
/* Same on the basis of cheapest startup cost ... */
innerpath = get_cheapest_path_for_pathkeys(innerrel->pathlist,
trialsortkeys,
NULL,
STARTUP_COST,
is_partial);
if (innerpath != NULL &&
(cheapest_startup_inner == NULL ||
compare_path_costs(innerpath, cheapest_startup_inner,
STARTUP_COST) < 0))
{
/* Found a cheap (or even-cheaper) sorted path */
if (innerpath != cheapest_total_inner)
{
/*
* Avoid rebuilding clause list if we already made one; saves
* memory in big join trees...
*/
if (newclauses == NIL)
{
if (sortkeycnt < num_sortkeys)
{
newclauses =
trim_mergeclauses_for_inner_pathkeys(root,
mergeclauses,
trialsortkeys);
Assert(newclauses != NIL);
}
else
newclauses = mergeclauses;
}
try_mergejoin_path(root,
joinrel,
outerpath,
innerpath,
merge_pathkeys,
newclauses,
NIL,
NIL,
jointype,
extra,
is_partial);
}
cheapest_startup_inner = innerpath;
}
/*
* Don't consider truncated sortkeys if we need all clauses.
*/
if (useallclauses)
break;
}
}
/*
* match_unsorted_outer
* Creates possible join paths for processing a single join relation
* 'joinrel' by employing either iterative substitution or
* mergejoining on each of its possible outer paths (considering
* only outer paths that are already ordered well enough for merging).
*
* We always generate a nestloop path for each available outer path.
* In fact we may generate as many as five: one on the cheapest-total-cost
* inner path, one on the same with materialization, one on the
* cheapest-startup-cost inner path (if different), one on the
* cheapest-total inner-indexscan path (if any), and one on the
* cheapest-startup inner-indexscan path (if different).
*
* We also consider mergejoins if mergejoin clauses are available. See
* detailed comments in generate_mergejoin_paths.
*
* 'joinrel' is the join relation
* 'outerrel' is the outer join relation
* 'innerrel' is the inner join relation
* 'jointype' is the type of join to do
* 'extra' contains additional input values
*/
static void
match_unsorted_outer(PlannerInfo *root,
RelOptInfo *joinrel,
RelOptInfo *outerrel,
RelOptInfo *innerrel,
JoinType jointype,
JoinPathExtraData *extra)
{
JoinType save_jointype = jointype;
bool nestjoinOK;
bool useallclauses;
Path *inner_cheapest_total = innerrel->cheapest_total_path;
Path *matpath = NULL;
ListCell *lc1;
/*
* Nestloop only supports inner, left, semi, and anti joins. Also, if we
* are doing a right or full mergejoin, we must use *all* the mergeclauses
* as join clauses, else we will not have a valid plan. (Although these
* two flags are currently inverses, keep them separate for clarity and
* possible future changes.)
*/
switch (jointype)
{
case JOIN_INNER:
case JOIN_LEFT:
case JOIN_SEMI:
case JOIN_ANTI:
nestjoinOK = true;
useallclauses = false;
break;
case JOIN_RIGHT:
case JOIN_FULL:
nestjoinOK = false;
useallclauses = true;
break;
case JOIN_UNIQUE_OUTER:
case JOIN_UNIQUE_INNER:
jointype = JOIN_INNER;
nestjoinOK = true;
useallclauses = false;
break;
default:
elog(ERROR, "unrecognized join type: %d",
(int) jointype);
nestjoinOK = false; /* keep compiler quiet */
useallclauses = false;
break;
}
/*
* If inner_cheapest_total is parameterized by the outer rel, ignore it;
* we will consider it below as a member of cheapest_parameterized_paths,
* but the other possibilities considered in this routine aren't usable.
*/
if (PATH_PARAM_BY_REL(inner_cheapest_total, outerrel))
inner_cheapest_total = NULL;
/*
* If we need to unique-ify the inner path, we will consider only the
* cheapest-total inner.
*/
if (save_jointype == JOIN_UNIQUE_INNER)
{
/* No way to do this with an inner path parameterized by outer rel */
if (inner_cheapest_total == NULL)
return;
inner_cheapest_total = (Path *)
create_unique_path(root, innerrel, inner_cheapest_total, extra->sjinfo);
Assert(inner_cheapest_total);
}
else if (nestjoinOK)
{
/*
* Consider materializing the cheapest inner path, unless
* enable_material is off or the path in question materializes its
* output anyway.
*/
if (enable_material && inner_cheapest_total != NULL &&
!ExecMaterializesOutput(inner_cheapest_total->pathtype))
matpath = (Path *)
create_material_path(innerrel, inner_cheapest_total);
}
foreach(lc1, outerrel->pathlist)
{
Path *outerpath = (Path *) lfirst(lc1);
List *merge_pathkeys;
/*
* We cannot use an outer path that is parameterized by the inner rel.
*/
if (PATH_PARAM_BY_REL(outerpath, innerrel))
continue;
/*
* If we need to unique-ify the outer path, it's pointless to consider
* any but the cheapest outer. (XXX we don't consider parameterized
* outers, nor inners, for unique-ified cases. Should we?)
*/
if (save_jointype == JOIN_UNIQUE_OUTER)
{
if (outerpath != outerrel->cheapest_total_path)
continue;
outerpath = (Path *) create_unique_path(root, outerrel,
outerpath, extra->sjinfo);
Assert(outerpath);
}
/*
* The result will have this sort order (even if it is implemented as
* a nestloop, and even if some of the mergeclauses are implemented by
* qpquals rather than as true mergeclauses):
*/
merge_pathkeys = build_join_pathkeys(root, joinrel, jointype,
outerpath->pathkeys);
if (save_jointype == JOIN_UNIQUE_INNER)
{
/*
* Consider nestloop join, but only with the unique-ified cheapest
* inner path
*/
try_nestloop_path(root,
joinrel,
outerpath,
inner_cheapest_total,
merge_pathkeys,
jointype,
extra);
}
else if (nestjoinOK)
{
/*
* Consider nestloop joins using this outer path and various
* available paths for the inner relation. We consider the
* cheapest-total paths for each available parameterization of the
* inner relation, including the unparameterized case.
*/
ListCell *lc2;
foreach(lc2, innerrel->cheapest_parameterized_paths)
{
Path *innerpath = (Path *) lfirst(lc2);
Path *mpath;
try_nestloop_path(root,
joinrel,
outerpath,
innerpath,
merge_pathkeys,
jointype,
extra);
/*
* Try generating a memoize path and see if that makes the
* nested loop any cheaper.
*/
mpath = get_memoize_path(root, innerrel, outerrel,
innerpath, outerpath, jointype,
extra);
if (mpath != NULL)
try_nestloop_path(root,
joinrel,
outerpath,
mpath,
merge_pathkeys,
jointype,
extra);
}
/* Also consider materialized form of the cheapest inner path */
if (matpath != NULL)
try_nestloop_path(root,
joinrel,
outerpath,
matpath,
merge_pathkeys,
jointype,
extra);
}
/* Can't do anything else if outer path needs to be unique'd */
if (save_jointype == JOIN_UNIQUE_OUTER)
continue;
/* Can't do anything else if inner rel is parameterized by outer */
if (inner_cheapest_total == NULL)
continue;
/* Generate merge join paths */
generate_mergejoin_paths(root, joinrel, innerrel, outerpath,
save_jointype, extra, useallclauses,
inner_cheapest_total, merge_pathkeys,
false);
}
/*
* Consider partial nestloop and mergejoin plan if outerrel has any
* partial path and the joinrel is parallel-safe. However, we can't
* handle JOIN_UNIQUE_OUTER, because the outer path will be partial, and
* therefore we won't be able to properly guarantee uniqueness. Nor can
* we handle joins needing lateral rels, since partial paths must not be
* parameterized. Similarly, we can't handle JOIN_FULL and JOIN_RIGHT,
* because they can produce false null extended rows.
*/
if (joinrel->consider_parallel &&
save_jointype != JOIN_UNIQUE_OUTER &&
save_jointype != JOIN_FULL &&
save_jointype != JOIN_RIGHT &&
outerrel->partial_pathlist != NIL &&
bms_is_empty(joinrel->lateral_relids))
{
if (nestjoinOK)
consider_parallel_nestloop(root, joinrel, outerrel, innerrel,
save_jointype, extra);
/*
* If inner_cheapest_total is NULL or non parallel-safe then find the
* cheapest total parallel safe path. If doing JOIN_UNIQUE_INNER, we
* can't use any alternative inner path.
*/
if (inner_cheapest_total == NULL ||
!inner_cheapest_total->parallel_safe)
{
if (save_jointype == JOIN_UNIQUE_INNER)
return;
inner_cheapest_total = get_cheapest_parallel_safe_total_inner(innerrel->pathlist);
}
if (inner_cheapest_total)
consider_parallel_mergejoin(root, joinrel, outerrel, innerrel,
save_jointype, extra,
inner_cheapest_total);
}
}
/*
* consider_parallel_mergejoin
* Try to build partial paths for a joinrel by joining a partial path
* for the outer relation to a complete path for the inner relation.
*
* 'joinrel' is the join relation
* 'outerrel' is the outer join relation
* 'innerrel' is the inner join relation
* 'jointype' is the type of join to do
* 'extra' contains additional input values
* 'inner_cheapest_total' cheapest total path for innerrel
*/
static void
consider_parallel_mergejoin(PlannerInfo *root,
RelOptInfo *joinrel,
RelOptInfo *outerrel,
RelOptInfo *innerrel,
JoinType jointype,
JoinPathExtraData *extra,
Path *inner_cheapest_total)
{
ListCell *lc1;
/* generate merge join path for each partial outer path */
foreach(lc1, outerrel->partial_pathlist)
{
Path *outerpath = (Path *) lfirst(lc1);
List *merge_pathkeys;
/*
* Figure out what useful ordering any paths we create will have.
*/
merge_pathkeys = build_join_pathkeys(root, joinrel, jointype,
outerpath->pathkeys);
generate_mergejoin_paths(root, joinrel, innerrel, outerpath, jointype,
extra, false, inner_cheapest_total,
merge_pathkeys, true);
}
}
/*
* consider_parallel_nestloop
* Try to build partial paths for a joinrel by joining a partial path for the
* outer relation to a complete path for the inner relation.
*
* 'joinrel' is the join relation
* 'outerrel' is the outer join relation
* 'innerrel' is the inner join relation
* 'jointype' is the type of join to do
* 'extra' contains additional input values
*/
static void
consider_parallel_nestloop(PlannerInfo *root,
RelOptInfo *joinrel,
RelOptInfo *outerrel,
RelOptInfo *innerrel,
JoinType jointype,
JoinPathExtraData *extra)
{
JoinType save_jointype = jointype;
ListCell *lc1;
if (jointype == JOIN_UNIQUE_INNER)
jointype = JOIN_INNER;
foreach(lc1, outerrel->partial_pathlist)
{
Path *outerpath = (Path *) lfirst(lc1);
List *pathkeys;
ListCell *lc2;
/* Figure out what useful ordering any paths we create will have. */
pathkeys = build_join_pathkeys(root, joinrel, jointype,
outerpath->pathkeys);
/*
* Try the cheapest parameterized paths; only those which will produce
* an unparameterized path when joined to this outerrel will survive
* try_partial_nestloop_path. The cheapest unparameterized path is
* also in this list.
*/
foreach(lc2, innerrel->cheapest_parameterized_paths)
{
Path *innerpath = (Path *) lfirst(lc2);
Path *mpath;
/* Can't join to an inner path that is not parallel-safe */
if (!innerpath->parallel_safe)
continue;
/*
* If we're doing JOIN_UNIQUE_INNER, we can only use the inner's
* cheapest_total_path, and we have to unique-ify it. (We might
* be able to relax this to allow other safe, unparameterized
* inner paths, but right now create_unique_path is not on board
* with that.)
*/
if (save_jointype == JOIN_UNIQUE_INNER)
{
if (innerpath != innerrel->cheapest_total_path)
continue;
innerpath = (Path *) create_unique_path(root, innerrel,
innerpath,
extra->sjinfo);
Assert(innerpath);
}
try_partial_nestloop_path(root, joinrel, outerpath, innerpath,
pathkeys, jointype, extra);
/*
* Try generating a memoize path and see if that makes the nested
* loop any cheaper.
*/
mpath = get_memoize_path(root, innerrel, outerrel,
innerpath, outerpath, jointype,
extra);
if (mpath != NULL)
try_partial_nestloop_path(root, joinrel, outerpath, mpath,
pathkeys, jointype, extra);
}
}
}
/*
* hash_inner_and_outer
* Create hashjoin join paths by explicitly hashing both the outer and
* inner keys of each available hash clause.
*
* 'joinrel' is the join relation
* 'outerrel' is the outer join relation
* 'innerrel' is the inner join relation
* 'jointype' is the type of join to do
* 'extra' contains additional input values
*/
static void
hash_inner_and_outer(PlannerInfo *root,
RelOptInfo *joinrel,
RelOptInfo *outerrel,
RelOptInfo *innerrel,
JoinType jointype,
JoinPathExtraData *extra)
{
JoinType save_jointype = jointype;
bool isouterjoin = IS_OUTER_JOIN(jointype);
List *hashclauses;
ListCell *l;
/*
* We need to build only one hashclauses list for any given pair of outer
* and inner relations; all of the hashable clauses will be used as keys.
*
* Scan the join's restrictinfo list to find hashjoinable clauses that are
* usable with this pair of sub-relations.
*/
hashclauses = NIL;
foreach(l, extra->restrictlist)
{
RestrictInfo *restrictinfo = (RestrictInfo *) lfirst(l);
/*
* If processing an outer join, only use its own join clauses for
* hashing. For inner joins we need not be so picky.
*/
if (isouterjoin && RINFO_IS_PUSHED_DOWN(restrictinfo, joinrel->relids))
continue;
if (!restrictinfo->can_join ||
restrictinfo->hashjoinoperator == InvalidOid)
continue; /* not hashjoinable */
/*
* Check if clause has the form "outer op inner" or "inner op outer".
*/
if (!clause_sides_match_join(restrictinfo, outerrel, innerrel))
continue; /* no good for these input relations */
hashclauses = lappend(hashclauses, restrictinfo);
}
/* If we found any usable hashclauses, make paths */
if (hashclauses)
{
/*
* We consider both the cheapest-total-cost and cheapest-startup-cost
* outer paths. There's no need to consider any but the
* cheapest-total-cost inner path, however.
*/
Path *cheapest_startup_outer = outerrel->cheapest_startup_path;
Path *cheapest_total_outer = outerrel->cheapest_total_path;
Path *cheapest_total_inner = innerrel->cheapest_total_path;
/*
* If either cheapest-total path is parameterized by the other rel, we
* can't use a hashjoin. (There's no use looking for alternative
* input paths, since these should already be the least-parameterized
* available paths.)
*/
if (PATH_PARAM_BY_REL(cheapest_total_outer, innerrel) ||
PATH_PARAM_BY_REL(cheapest_total_inner, outerrel))
return;
/* Unique-ify if need be; we ignore parameterized possibilities */
if (jointype == JOIN_UNIQUE_OUTER)
{
cheapest_total_outer = (Path *)
create_unique_path(root, outerrel,
cheapest_total_outer, extra->sjinfo);
Assert(cheapest_total_outer);
jointype = JOIN_INNER;
try_hashjoin_path(root,
joinrel,
cheapest_total_outer,
cheapest_total_inner,
hashclauses,
jointype,
extra);
/* no possibility of cheap startup here */
}
else if (jointype == JOIN_UNIQUE_INNER)
{
cheapest_total_inner = (Path *)
create_unique_path(root, innerrel,
cheapest_total_inner, extra->sjinfo);
Assert(cheapest_total_inner);
jointype = JOIN_INNER;
try_hashjoin_path(root,
joinrel,
cheapest_total_outer,
cheapest_total_inner,
hashclauses,
jointype,
extra);
if (cheapest_startup_outer != NULL &&
cheapest_startup_outer != cheapest_total_outer)
try_hashjoin_path(root,
joinrel,
cheapest_startup_outer,
cheapest_total_inner,
hashclauses,
jointype,
extra);
}
else
{
/*
* For other jointypes, we consider the cheapest startup outer
* together with the cheapest total inner, and then consider
* pairings of cheapest-total paths including parameterized ones.
* There is no use in generating parameterized paths on the basis
* of possibly cheap startup cost, so this is sufficient.
*/
ListCell *lc1;
ListCell *lc2;
if (cheapest_startup_outer != NULL)
try_hashjoin_path(root,
joinrel,
cheapest_startup_outer,
cheapest_total_inner,
hashclauses,
jointype,
extra);
foreach(lc1, outerrel->cheapest_parameterized_paths)
{
Path *outerpath = (Path *) lfirst(lc1);
/*
* We cannot use an outer path that is parameterized by the
* inner rel.
*/
if (PATH_PARAM_BY_REL(outerpath, innerrel))
continue;
foreach(lc2, innerrel->cheapest_parameterized_paths)
{
Path *innerpath = (Path *) lfirst(lc2);
/*
* We cannot use an inner path that is parameterized by
* the outer rel, either.
*/
if (PATH_PARAM_BY_REL(innerpath, outerrel))
continue;
if (outerpath == cheapest_startup_outer &&
innerpath == cheapest_total_inner)
continue; /* already tried it */
try_hashjoin_path(root,
joinrel,
outerpath,
innerpath,
hashclauses,
jointype,
extra);
}
}
}
/*
* If the joinrel is parallel-safe, we may be able to consider a
* partial hash join. However, we can't handle JOIN_UNIQUE_OUTER,
* because the outer path will be partial, and therefore we won't be
* able to properly guarantee uniqueness. Similarly, we can't handle
* JOIN_FULL and JOIN_RIGHT, because they can produce false null
* extended rows. Also, the resulting path must not be parameterized.
* We would be able to support JOIN_FULL and JOIN_RIGHT for Parallel
* Hash, since in that case we're back to a single hash table with a
* single set of match bits for each batch, but that will require
* figuring out a deadlock-free way to wait for the probe to finish.
*/
if (joinrel->consider_parallel &&
save_jointype != JOIN_UNIQUE_OUTER &&
save_jointype != JOIN_FULL &&
save_jointype != JOIN_RIGHT &&
outerrel->partial_pathlist != NIL &&
bms_is_empty(joinrel->lateral_relids))
{
Path *cheapest_partial_outer;
Path *cheapest_partial_inner = NULL;
Path *cheapest_safe_inner = NULL;
cheapest_partial_outer =
(Path *) linitial(outerrel->partial_pathlist);
/*
* Can we use a partial inner plan too, so that we can build a
* shared hash table in parallel? We can't handle
* JOIN_UNIQUE_INNER because we can't guarantee uniqueness.
*/
if (innerrel->partial_pathlist != NIL &&
save_jointype != JOIN_UNIQUE_INNER &&
enable_parallel_hash)
{
cheapest_partial_inner =
(Path *) linitial(innerrel->partial_pathlist);
try_partial_hashjoin_path(root, joinrel,
cheapest_partial_outer,
cheapest_partial_inner,
hashclauses, jointype, extra,
true /* parallel_hash */ );
}
/*
* Normally, given that the joinrel is parallel-safe, the cheapest
* total inner path will also be parallel-safe, but if not, we'll
* have to search for the cheapest safe, unparameterized inner
* path. If doing JOIN_UNIQUE_INNER, we can't use any alternative
* inner path.
*/
if (cheapest_total_inner->parallel_safe)
cheapest_safe_inner = cheapest_total_inner;
else if (save_jointype != JOIN_UNIQUE_INNER)
cheapest_safe_inner =
get_cheapest_parallel_safe_total_inner(innerrel->pathlist);
if (cheapest_safe_inner != NULL)
try_partial_hashjoin_path(root, joinrel,
cheapest_partial_outer,
cheapest_safe_inner,
hashclauses, jointype, extra,
false /* parallel_hash */ );
}
}
}
/*
* select_mergejoin_clauses
* Select mergejoin clauses that are usable for a particular join.
* Returns a list of RestrictInfo nodes for those clauses.
*
* *mergejoin_allowed is normally set to true, but it is set to false if
* this is a right/full join and there are nonmergejoinable join clauses.
* The executor's mergejoin machinery cannot handle such cases, so we have
* to avoid generating a mergejoin plan. (Note that this flag does NOT
* consider whether there are actually any mergejoinable clauses. This is
* correct because in some cases we need to build a clauseless mergejoin.
* Simply returning NIL is therefore not enough to distinguish safe from
* unsafe cases.)
*
* We also mark each selected RestrictInfo to show which side is currently
* being considered as outer. These are transient markings that are only
* good for the duration of the current add_paths_to_joinrel() call!
*
* We examine each restrictinfo clause known for the join to see
* if it is mergejoinable and involves vars from the two sub-relations
* currently of interest.
*/
static List *
select_mergejoin_clauses(PlannerInfo *root,
RelOptInfo *joinrel,
RelOptInfo *outerrel,
RelOptInfo *innerrel,
List *restrictlist,
JoinType jointype,
bool *mergejoin_allowed)
{
List *result_list = NIL;
bool isouterjoin = IS_OUTER_JOIN(jointype);
bool have_nonmergeable_joinclause = false;
ListCell *l;
foreach(l, restrictlist)
{
RestrictInfo *restrictinfo = (RestrictInfo *) lfirst(l);
/*
* If processing an outer join, only use its own join clauses in the
* merge. For inner joins we can use pushed-down clauses too. (Note:
* we don't set have_nonmergeable_joinclause here because pushed-down
* clauses will become otherquals not joinquals.)
*/
if (isouterjoin && RINFO_IS_PUSHED_DOWN(restrictinfo, joinrel->relids))
continue;
/* Check that clause is a mergeable operator clause */
if (!restrictinfo->can_join ||
restrictinfo->mergeopfamilies == NIL)
{
/*
* The executor can handle extra joinquals that are constants, but
* not anything else, when doing right/full merge join. (The
* reason to support constants is so we can do FULL JOIN ON
* FALSE.)
*/
if (!restrictinfo->clause || !IsA(restrictinfo->clause, Const))
have_nonmergeable_joinclause = true;
continue; /* not mergejoinable */
}
/*
* Check if clause has the form "outer op inner" or "inner op outer".
*/
if (!clause_sides_match_join(restrictinfo, outerrel, innerrel))
{
have_nonmergeable_joinclause = true;
continue; /* no good for these input relations */
}
/*
* Insist that each side have a non-redundant eclass. This
* restriction is needed because various bits of the planner expect
* that each clause in a merge be associable with some pathkey in a
* canonical pathkey list, but redundant eclasses can't appear in
* canonical sort orderings. (XXX it might be worth relaxing this,
* but not enough time to address it for 8.3.)
*
* Note: it would be bad if this condition failed for an otherwise
* mergejoinable FULL JOIN clause, since that would result in
* undesirable planner failure. I believe that is not possible
* however; a variable involved in a full join could only appear in
* below_outer_join eclasses, which aren't considered redundant.
*
* This case *can* happen for left/right join clauses: the outer-side
* variable could be equated to a constant. Because we will propagate
* that constant across the join clause, the loss of ability to do a
* mergejoin is not really all that big a deal, and so it's not clear
* that improving this is important.
*/
update_mergeclause_eclasses(root, restrictinfo);
if (EC_MUST_BE_REDUNDANT(restrictinfo->left_ec) ||
EC_MUST_BE_REDUNDANT(restrictinfo->right_ec))
{
have_nonmergeable_joinclause = true;
continue; /* can't handle redundant eclasses */
}
result_list = lappend(result_list, restrictinfo);
}
/*
* Report whether mergejoin is allowed (see comment at top of function).
*/
switch (jointype)
{
case JOIN_RIGHT:
case JOIN_FULL:
*mergejoin_allowed = !have_nonmergeable_joinclause;
break;
default:
*mergejoin_allowed = true;
break;
}
return result_list;
}
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