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postgres/src/backend/optimizer/util/plancat.c
Alvaro Herrera 05fb5d6619 Ignore partitioned indexes where appropriate 
get_relation_info() was too optimistic about opening indexes in
partitioned tables, which would raise errors when any queries were
planned on such tables.  Fix by ignoring any indexes of the partitioned
kind.

CLUSTER (and ALTER TABLE CLUSTER ON) had a similar problem.  Fix by
disallowing these commands in partitioned tables.

Fallout from 8b08f7d4820f.
2018-01-25 16:12:15 -03:00

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/*-------------------------------------------------------------------------
*
* plancat.c
* routines for accessing the system catalogs
*
*
* Portions Copyright (c) 1996-2018, PostgreSQL Global Development Group
* Portions Copyright (c) 1994, Regents of the University of California
*
*
* IDENTIFICATION
* src/backend/optimizer/util/plancat.c
*
*-------------------------------------------------------------------------
*/
#include "postgres.h"
#include <math.h>
#include "access/genam.h"
#include "access/heapam.h"
#include "access/htup_details.h"
#include "access/nbtree.h"
#include "access/sysattr.h"
#include "access/transam.h"
#include "access/xlog.h"
#include "catalog/catalog.h"
#include "catalog/dependency.h"
#include "catalog/heap.h"
#include "catalog/partition.h"
#include "catalog/pg_am.h"
#include "catalog/pg_statistic_ext.h"
#include "foreign/fdwapi.h"
#include "miscadmin.h"
#include "nodes/makefuncs.h"
#include "optimizer/clauses.h"
#include "optimizer/cost.h"
#include "optimizer/plancat.h"
#include "optimizer/predtest.h"
#include "optimizer/prep.h"
#include "parser/parse_relation.h"
#include "parser/parsetree.h"
#include "rewrite/rewriteManip.h"
#include "statistics/statistics.h"
#include "storage/bufmgr.h"
#include "utils/builtins.h"
#include "utils/lsyscache.h"
#include "utils/syscache.h"
#include "utils/rel.h"
#include "utils/snapmgr.h"
/* GUC parameter */
int constraint_exclusion = CONSTRAINT_EXCLUSION_PARTITION;
/* Hook for plugins to get control in get_relation_info() */
get_relation_info_hook_type get_relation_info_hook = NULL;
static void get_relation_foreign_keys(PlannerInfo *root, RelOptInfo *rel,
Relation relation, bool inhparent);
static bool infer_collation_opclass_match(InferenceElem *elem, Relation idxRel,
List *idxExprs);
static int32 get_rel_data_width(Relation rel, int32 *attr_widths);
static List *get_relation_constraints(PlannerInfo *root,
Oid relationObjectId, RelOptInfo *rel,
bool include_notnull);
static List *build_index_tlist(PlannerInfo *root, IndexOptInfo *index,
Relation heapRelation);
static List *get_relation_statistics(RelOptInfo *rel, Relation relation);
static void set_relation_partition_info(PlannerInfo *root, RelOptInfo *rel,
Relation relation);
static PartitionScheme find_partition_scheme(PlannerInfo *root, Relation rel);
static void set_baserel_partition_key_exprs(Relation relation,
RelOptInfo *rel);
/*
* get_relation_info -
* Retrieves catalog information for a given relation.
*
* Given the Oid of the relation, return the following info into fields
* of the RelOptInfo struct:
*
* min_attr lowest valid AttrNumber
* max_attr highest valid AttrNumber
* indexlist list of IndexOptInfos for relation's indexes
* statlist list of StatisticExtInfo for relation's statistic objects
* serverid if it's a foreign table, the server OID
* fdwroutine if it's a foreign table, the FDW function pointers
* pages number of pages
* tuples number of tuples
* rel_parallel_workers user-defined number of parallel workers
*
* Also, add information about the relation's foreign keys to root->fkey_list.
*
* Also, initialize the attr_needed[] and attr_widths[] arrays. In most
* cases these are left as zeroes, but sometimes we need to compute attr
* widths here, and we may as well cache the results for costsize.c.
*
* If inhparent is true, all we need to do is set up the attr arrays:
* the RelOptInfo actually represents the appendrel formed by an inheritance
* tree, and so the parent rel's physical size and index information isn't
* important for it.
*/
void
get_relation_info(PlannerInfo *root, Oid relationObjectId, bool inhparent,
RelOptInfo *rel)
{
Index varno = rel->relid;
Relation relation;
bool hasindex;
List *indexinfos = NIL;
/*
* We need not lock the relation since it was already locked, either by
* the rewriter or when expand_inherited_rtentry() added it to the query's
* rangetable.
*/
relation = heap_open(relationObjectId, NoLock);
/* Temporary and unlogged relations are inaccessible during recovery. */
if (!RelationNeedsWAL(relation) && RecoveryInProgress())
ereport(ERROR,
(errcode(ERRCODE_FEATURE_NOT_SUPPORTED),
errmsg("cannot access temporary or unlogged relations during recovery")));
rel->min_attr = FirstLowInvalidHeapAttributeNumber + 1;
rel->max_attr = RelationGetNumberOfAttributes(relation);
rel->reltablespace = RelationGetForm(relation)->reltablespace;
Assert(rel->max_attr >= rel->min_attr);
rel->attr_needed = (Relids *)
palloc0((rel->max_attr - rel->min_attr + 1) * sizeof(Relids));
rel->attr_widths = (int32 *)
palloc0((rel->max_attr - rel->min_attr + 1) * sizeof(int32));
/*
* Estimate relation size --- unless it's an inheritance parent, in which
* case the size will be computed later in set_append_rel_pathlist, and we
* must leave it zero for now to avoid bollixing the total_table_pages
* calculation.
*/
if (!inhparent)
estimate_rel_size(relation, rel->attr_widths - rel->min_attr,
&rel->pages, &rel->tuples, &rel->allvisfrac);
/* Retrieve the parallel_workers reloption, or -1 if not set. */
rel->rel_parallel_workers = RelationGetParallelWorkers(relation, -1);
/*
* Make list of indexes. Ignore indexes on system catalogs if told to.
* Don't bother with indexes for an inheritance parent, either.
*/
if (inhparent ||
(IgnoreSystemIndexes && IsSystemRelation(relation)))
hasindex = false;
else
hasindex = relation->rd_rel->relhasindex;
if (hasindex)
{
List *indexoidlist;
ListCell *l;
LOCKMODE lmode;
indexoidlist = RelationGetIndexList(relation);
/*
* For each index, we get the same type of lock that the executor will
* need, and do not release it. This saves a couple of trips to the
* shared lock manager while not creating any real loss of
* concurrency, because no schema changes could be happening on the
* index while we hold lock on the parent rel, and neither lock type
* blocks any other kind of index operation.
*/
if (rel->relid == root->parse->resultRelation)
lmode = RowExclusiveLock;
else
lmode = AccessShareLock;
foreach(l, indexoidlist)
{
Oid indexoid = lfirst_oid(l);
Relation indexRelation;
Form_pg_index index;
IndexAmRoutine *amroutine;
IndexOptInfo *info;
int ncolumns;
int i;
/*
* Extract info from the relation descriptor for the index.
*/
indexRelation = index_open(indexoid, lmode);
index = indexRelation->rd_index;
/*
* Ignore invalid indexes, since they can't safely be used for
* queries. Note that this is OK because the data structure we
* are constructing is only used by the planner --- the executor
* still needs to insert into "invalid" indexes, if they're marked
* IndexIsReady.
*/
if (!IndexIsValid(index))
{
index_close(indexRelation, NoLock);
continue;
}
/*
* Ignore partitioned indexes, since they are not usable for
* queries.
*/
if (indexRelation->rd_rel->relkind == RELKIND_PARTITIONED_INDEX)
{
index_close(indexRelation, NoLock);
continue;
}
/*
* If the index is valid, but cannot yet be used, ignore it; but
* mark the plan we are generating as transient. See
* src/backend/access/heap/README.HOT for discussion.
*/
if (index->indcheckxmin &&
!TransactionIdPrecedes(HeapTupleHeaderGetXmin(indexRelation->rd_indextuple->t_data),
TransactionXmin))
{
root->glob->transientPlan = true;
index_close(indexRelation, NoLock);
continue;
}
info = makeNode(IndexOptInfo);
info->indexoid = index->indexrelid;
info->reltablespace =
RelationGetForm(indexRelation)->reltablespace;
info->rel = rel;
info->ncolumns = ncolumns = index->indnatts;
info->indexkeys = (int *) palloc(sizeof(int) * ncolumns);
info->indexcollations = (Oid *) palloc(sizeof(Oid) * ncolumns);
info->opfamily = (Oid *) palloc(sizeof(Oid) * ncolumns);
info->opcintype = (Oid *) palloc(sizeof(Oid) * ncolumns);
info->canreturn = (bool *) palloc(sizeof(bool) * ncolumns);
for (i = 0; i < ncolumns; i++)
{
info->indexkeys[i] = index->indkey.values[i];
info->indexcollations[i] = indexRelation->rd_indcollation[i];
info->opfamily[i] = indexRelation->rd_opfamily[i];
info->opcintype[i] = indexRelation->rd_opcintype[i];
info->canreturn[i] = index_can_return(indexRelation, i + 1);
}
info->relam = indexRelation->rd_rel->relam;
/* We copy just the fields we need, not all of rd_amroutine */
amroutine = indexRelation->rd_amroutine;
info->amcanorderbyop = amroutine->amcanorderbyop;
info->amoptionalkey = amroutine->amoptionalkey;
info->amsearcharray = amroutine->amsearcharray;
info->amsearchnulls = amroutine->amsearchnulls;
info->amcanparallel = amroutine->amcanparallel;
info->amhasgettuple = (amroutine->amgettuple != NULL);
info->amhasgetbitmap = (amroutine->amgetbitmap != NULL);
info->amcostestimate = amroutine->amcostestimate;
Assert(info->amcostestimate != NULL);
/*
* Fetch the ordering information for the index, if any.
*/
if (info->relam == BTREE_AM_OID)
{
/*
* If it's a btree index, we can use its opfamily OIDs
* directly as the sort ordering opfamily OIDs.
*/
Assert(amroutine->amcanorder);
info->sortopfamily = info->opfamily;
info->reverse_sort = (bool *) palloc(sizeof(bool) * ncolumns);
info->nulls_first = (bool *) palloc(sizeof(bool) * ncolumns);
for (i = 0; i < ncolumns; i++)
{
int16 opt = indexRelation->rd_indoption[i];
info->reverse_sort[i] = (opt & INDOPTION_DESC) != 0;
info->nulls_first[i] = (opt & INDOPTION_NULLS_FIRST) != 0;
}
}
else if (amroutine->amcanorder)
{
/*
* Otherwise, identify the corresponding btree opfamilies by
* trying to map this index's "<" operators into btree. Since
* "<" uniquely defines the behavior of a sort order, this is
* a sufficient test.
*
* XXX This method is rather slow and also requires the
* undesirable assumption that the other index AM numbers its
* strategies the same as btree. It'd be better to have a way
* to explicitly declare the corresponding btree opfamily for
* each opfamily of the other index type. But given the lack
* of current or foreseeable amcanorder index types, it's not
* worth expending more effort on now.
*/
info->sortopfamily = (Oid *) palloc(sizeof(Oid) * ncolumns);
info->reverse_sort = (bool *) palloc(sizeof(bool) * ncolumns);
info->nulls_first = (bool *) palloc(sizeof(bool) * ncolumns);
for (i = 0; i < ncolumns; i++)
{
int16 opt = indexRelation->rd_indoption[i];
Oid ltopr;
Oid btopfamily;
Oid btopcintype;
int16 btstrategy;
info->reverse_sort[i] = (opt & INDOPTION_DESC) != 0;
info->nulls_first[i] = (opt & INDOPTION_NULLS_FIRST) != 0;
ltopr = get_opfamily_member(info->opfamily[i],
info->opcintype[i],
info->opcintype[i],
BTLessStrategyNumber);
if (OidIsValid(ltopr) &&
get_ordering_op_properties(ltopr,
&btopfamily,
&btopcintype,
&btstrategy) &&
btopcintype == info->opcintype[i] &&
btstrategy == BTLessStrategyNumber)
{
/* Successful mapping */
info->sortopfamily[i] = btopfamily;
}
else
{
/* Fail ... quietly treat index as unordered */
info->sortopfamily = NULL;
info->reverse_sort = NULL;
info->nulls_first = NULL;
break;
}
}
}
else
{
info->sortopfamily = NULL;
info->reverse_sort = NULL;
info->nulls_first = NULL;
}
/*
* Fetch the index expressions and predicate, if any. We must
* modify the copies we obtain from the relcache to have the
* correct varno for the parent relation, so that they match up
* correctly against qual clauses.
*/
info->indexprs = RelationGetIndexExpressions(indexRelation);
info->indpred = RelationGetIndexPredicate(indexRelation);
if (info->indexprs && varno != 1)
ChangeVarNodes((Node *) info->indexprs, 1, varno, 0);
if (info->indpred && varno != 1)
ChangeVarNodes((Node *) info->indpred, 1, varno, 0);
/* Build targetlist using the completed indexprs data */
info->indextlist = build_index_tlist(root, info, relation);
info->indrestrictinfo = NIL; /* set later, in indxpath.c */
info->predOK = false; /* set later, in indxpath.c */
info->unique = index->indisunique;
info->immediate = index->indimmediate;
info->hypothetical = false;
/*
* Estimate the index size. If it's not a partial index, we lock
* the number-of-tuples estimate to equal the parent table; if it
* is partial then we have to use the same methods as we would for
* a table, except we can be sure that the index is not larger
* than the table.
*/
if (info->indpred == NIL)
{
info->pages = RelationGetNumberOfBlocks(indexRelation);
info->tuples = rel->tuples;
}
else
{
double allvisfrac; /* dummy */
estimate_rel_size(indexRelation, NULL,
&info->pages, &info->tuples, &allvisfrac);
if (info->tuples > rel->tuples)
info->tuples = rel->tuples;
}
if (info->relam == BTREE_AM_OID)
{
/* For btrees, get tree height while we have the index open */
info->tree_height = _bt_getrootheight(indexRelation);
}
else
{
/* For other index types, just set it to "unknown" for now */
info->tree_height = -1;
}
index_close(indexRelation, NoLock);
indexinfos = lcons(info, indexinfos);
}
list_free(indexoidlist);
}
rel->indexlist = indexinfos;
rel->statlist = get_relation_statistics(rel, relation);
/* Grab foreign-table info using the relcache, while we have it */
if (relation->rd_rel->relkind == RELKIND_FOREIGN_TABLE)
{
rel->serverid = GetForeignServerIdByRelId(RelationGetRelid(relation));
rel->fdwroutine = GetFdwRoutineForRelation(relation, true);
}
else
{
rel->serverid = InvalidOid;
rel->fdwroutine = NULL;
}
/* Collect info about relation's foreign keys, if relevant */
get_relation_foreign_keys(root, rel, relation, inhparent);
/*
* Collect info about relation's partitioning scheme, if any. Only
* inheritance parents may be partitioned.
*/
if (inhparent && relation->rd_rel->relkind == RELKIND_PARTITIONED_TABLE)
set_relation_partition_info(root, rel, relation);
heap_close(relation, NoLock);
/*
* Allow a plugin to editorialize on the info we obtained from the
* catalogs. Actions might include altering the assumed relation size,
* removing an index, or adding a hypothetical index to the indexlist.
*/
if (get_relation_info_hook)
(*get_relation_info_hook) (root, relationObjectId, inhparent, rel);
}
/*
* get_relation_foreign_keys -
* Retrieves foreign key information for a given relation.
*
* ForeignKeyOptInfos for relevant foreign keys are created and added to
* root->fkey_list. We do this now while we have the relcache entry open.
* We could sometimes avoid making useless ForeignKeyOptInfos if we waited
* until all RelOptInfos have been built, but the cost of re-opening the
* relcache entries would probably exceed any savings.
*/
static void
get_relation_foreign_keys(PlannerInfo *root, RelOptInfo *rel,
Relation relation, bool inhparent)
{
List *rtable = root->parse->rtable;
List *cachedfkeys;
ListCell *lc;
/*
* If it's not a baserel, we don't care about its FKs. Also, if the query
* references only a single relation, we can skip the lookup since no FKs
* could satisfy the requirements below.
*/
if (rel->reloptkind != RELOPT_BASEREL ||
list_length(rtable) < 2)
return;
/*
* If it's the parent of an inheritance tree, ignore its FKs. We could
* make useful FK-based deductions if we found that all members of the
* inheritance tree have equivalent FK constraints, but detecting that
* would require code that hasn't been written.
*/
if (inhparent)
return;
/*
* Extract data about relation's FKs from the relcache. Note that this
* list belongs to the relcache and might disappear in a cache flush, so
* we must not do any further catalog access within this function.
*/
cachedfkeys = RelationGetFKeyList(relation);
/*
* Figure out which FKs are of interest for this query, and create
* ForeignKeyOptInfos for them. We want only FKs that reference some
* other RTE of the current query. In queries containing self-joins,
* there might be more than one other RTE for a referenced table, and we
* should make a ForeignKeyOptInfo for each occurrence.
*
* Ideally, we would ignore RTEs that correspond to non-baserels, but it's
* too hard to identify those here, so we might end up making some useless
* ForeignKeyOptInfos. If so, match_foreign_keys_to_quals() will remove
* them again.
*/
foreach(lc, cachedfkeys)
{
ForeignKeyCacheInfo *cachedfk = (ForeignKeyCacheInfo *) lfirst(lc);
Index rti;
ListCell *lc2;
/* conrelid should always be that of the table we're considering */
Assert(cachedfk->conrelid == RelationGetRelid(relation));
/* Scan to find other RTEs matching confrelid */
rti = 0;
foreach(lc2, rtable)
{
RangeTblEntry *rte = (RangeTblEntry *) lfirst(lc2);
ForeignKeyOptInfo *info;
rti++;
/* Ignore if not the correct table */
if (rte->rtekind != RTE_RELATION ||
rte->relid != cachedfk->confrelid)
continue;
/* Ignore if it's an inheritance parent; doesn't really match */
if (rte->inh)
continue;
/* Ignore self-referential FKs; we only care about joins */
if (rti == rel->relid)
continue;
/* OK, let's make an entry */
info = makeNode(ForeignKeyOptInfo);
info->con_relid = rel->relid;
info->ref_relid = rti;
info->nkeys = cachedfk->nkeys;
memcpy(info->conkey, cachedfk->conkey, sizeof(info->conkey));
memcpy(info->confkey, cachedfk->confkey, sizeof(info->confkey));
memcpy(info->conpfeqop, cachedfk->conpfeqop, sizeof(info->conpfeqop));
/* zero out fields to be filled by match_foreign_keys_to_quals */
info->nmatched_ec = 0;
info->nmatched_rcols = 0;
info->nmatched_ri = 0;
memset(info->eclass, 0, sizeof(info->eclass));
memset(info->rinfos, 0, sizeof(info->rinfos));
root->fkey_list = lappend(root->fkey_list, info);
}
}
}
/*
* infer_arbiter_indexes -
* Determine the unique indexes used to arbitrate speculative insertion.
*
* Uses user-supplied inference clause expressions and predicate to match a
* unique index from those defined and ready on the heap relation (target).
* An exact match is required on columns/expressions (although they can appear
* in any order). However, the predicate given by the user need only restrict
* insertion to a subset of some part of the table covered by some particular
* unique index (in particular, a partial unique index) in order to be
* inferred.
*
* The implementation does not consider which B-Tree operator class any
* particular available unique index attribute uses, unless one was specified
* in the inference specification. The same is true of collations. In
* particular, there is no system dependency on the default operator class for
* the purposes of inference. If no opclass (or collation) is specified, then
* all matching indexes (that may or may not match the default in terms of
* each attribute opclass/collation) are used for inference.
*/
List *
infer_arbiter_indexes(PlannerInfo *root)
{
OnConflictExpr *onconflict = root->parse->onConflict;
/* Iteration state */
Relation relation;
Oid relationObjectId;
Oid indexOidFromConstraint = InvalidOid;
List *indexList;
ListCell *l;
/* Normalized inference attributes and inference expressions: */
Bitmapset *inferAttrs = NULL;
List *inferElems = NIL;
/* Results */
List *results = NIL;
/*
* Quickly return NIL for ON CONFLICT DO NOTHING without an inference
* specification or named constraint. ON CONFLICT DO UPDATE statements
* must always provide one or the other (but parser ought to have caught
* that already).
*/
if (onconflict->arbiterElems == NIL &&
onconflict->constraint == InvalidOid)
return NIL;
/*
* We need not lock the relation since it was already locked, either by
* the rewriter or when expand_inherited_rtentry() added it to the query's
* rangetable.
*/
relationObjectId = rt_fetch(root->parse->resultRelation,
root->parse->rtable)->relid;
relation = heap_open(relationObjectId, NoLock);
/*
* Build normalized/BMS representation of plain indexed attributes, as
* well as a separate list of expression items. This simplifies matching
* the cataloged definition of indexes.
*/
foreach(l, onconflict->arbiterElems)
{
InferenceElem *elem = (InferenceElem *) lfirst(l);
Var *var;
int attno;
if (!IsA(elem->expr, Var))
{
/* If not a plain Var, just shove it in inferElems for now */
inferElems = lappend(inferElems, elem->expr);
continue;
}
var = (Var *) elem->expr;
attno = var->varattno;
if (attno == 0)
ereport(ERROR,
(errcode(ERRCODE_FEATURE_NOT_SUPPORTED),
errmsg("whole row unique index inference specifications are not supported")));
inferAttrs = bms_add_member(inferAttrs,
attno - FirstLowInvalidHeapAttributeNumber);
}
/*
* Lookup named constraint's index. This is not immediately returned
* because some additional sanity checks are required.
*/
if (onconflict->constraint != InvalidOid)
{
indexOidFromConstraint = get_constraint_index(onconflict->constraint);
if (indexOidFromConstraint == InvalidOid)
ereport(ERROR,
(errcode(ERRCODE_WRONG_OBJECT_TYPE),
errmsg("constraint in ON CONFLICT clause has no associated index")));
}
/*
* Using that representation, iterate through the list of indexes on the
* target relation to try and find a match
*/
indexList = RelationGetIndexList(relation);
foreach(l, indexList)
{
Oid indexoid = lfirst_oid(l);
Relation idxRel;
Form_pg_index idxForm;
Bitmapset *indexedAttrs;
List *idxExprs;
List *predExprs;
AttrNumber natt;
ListCell *el;
/*
* Extract info from the relation descriptor for the index. We know
* that this is a target, so get lock type it is known will ultimately
* be required by the executor.
*
* Let executor complain about !indimmediate case directly, because
* enforcement needs to occur there anyway when an inference clause is
* omitted.
*/
idxRel = index_open(indexoid, RowExclusiveLock);
idxForm = idxRel->rd_index;
if (!IndexIsValid(idxForm))
goto next;
/*
* Note that we do not perform a check against indcheckxmin (like e.g.
* get_relation_info()) here to eliminate candidates, because
* uniqueness checking only cares about the most recently committed
* tuple versions.
*/
/*
* Look for match on "ON constraint_name" variant, which may not be
* unique constraint. This can only be a constraint name.
*/
if (indexOidFromConstraint == idxForm->indexrelid)
{
if (!idxForm->indisunique && onconflict->action == ONCONFLICT_UPDATE)
ereport(ERROR,
(errcode(ERRCODE_WRONG_OBJECT_TYPE),
errmsg("ON CONFLICT DO UPDATE not supported with exclusion constraints")));
results = lappend_oid(results, idxForm->indexrelid);
list_free(indexList);
index_close(idxRel, NoLock);
heap_close(relation, NoLock);
return results;
}
else if (indexOidFromConstraint != InvalidOid)
{
/* No point in further work for index in named constraint case */
goto next;
}
/*
* Only considering conventional inference at this point (not named
* constraints), so index under consideration can be immediately
* skipped if it's not unique
*/
if (!idxForm->indisunique)
goto next;
/* Build BMS representation of plain (non expression) index attrs */
indexedAttrs = NULL;
for (natt = 0; natt < idxForm->indnatts; natt++)
{
int attno = idxRel->rd_index->indkey.values[natt];
if (attno != 0)
indexedAttrs = bms_add_member(indexedAttrs,
attno - FirstLowInvalidHeapAttributeNumber);
}
/* Non-expression attributes (if any) must match */
if (!bms_equal(indexedAttrs, inferAttrs))
goto next;
/* Expression attributes (if any) must match */
idxExprs = RelationGetIndexExpressions(idxRel);
foreach(el, onconflict->arbiterElems)
{
InferenceElem *elem = (InferenceElem *) lfirst(el);
/*
* Ensure that collation/opclass aspects of inference expression
* element match. Even though this loop is primarily concerned
* with matching expressions, it is a convenient point to check
* this for both expressions and ordinary (non-expression)
* attributes appearing as inference elements.
*/
if (!infer_collation_opclass_match(elem, idxRel, idxExprs))
goto next;
/*
* Plain Vars don't factor into count of expression elements, and
* the question of whether or not they satisfy the index
* definition has already been considered (they must).
*/
if (IsA(elem->expr, Var))
continue;
/*
* Might as well avoid redundant check in the rare cases where
* infer_collation_opclass_match() is required to do real work.
* Otherwise, check that element expression appears in cataloged
* index definition.
*/
if (elem->infercollid != InvalidOid ||
elem->inferopclass != InvalidOid ||
list_member(idxExprs, elem->expr))
continue;
goto next;
}
/*
* Now that all inference elements were matched, ensure that the
* expression elements from inference clause are not missing any
* cataloged expressions. This does the right thing when unique
* indexes redundantly repeat the same attribute, or if attributes
* redundantly appear multiple times within an inference clause.
*/
if (list_difference(idxExprs, inferElems) != NIL)
goto next;
/*
* If it's a partial index, its predicate must be implied by the ON
* CONFLICT's WHERE clause.
*/
predExprs = RelationGetIndexPredicate(idxRel);
if (!predicate_implied_by(predExprs, (List *) onconflict->arbiterWhere, false))
goto next;
results = lappend_oid(results, idxForm->indexrelid);
next:
index_close(idxRel, NoLock);
}
list_free(indexList);
heap_close(relation, NoLock);
if (results == NIL)
ereport(ERROR,
(errcode(ERRCODE_INVALID_COLUMN_REFERENCE),
errmsg("there is no unique or exclusion constraint matching the ON CONFLICT specification")));
return results;
}
/*
* infer_collation_opclass_match - ensure infer element opclass/collation match
*
* Given unique index inference element from inference specification, if
* collation was specified, or if opclass was specified, verify that there is
* at least one matching indexed attribute (occasionally, there may be more).
* Skip this in the common case where inference specification does not include
* collation or opclass (instead matching everything, regardless of cataloged
* collation/opclass of indexed attribute).
*
* At least historically, Postgres has not offered collations or opclasses
* with alternative-to-default notions of equality, so these additional
* criteria should only be required infrequently.
*
* Don't give up immediately when an inference element matches some attribute
* cataloged as indexed but not matching additional opclass/collation
* criteria. This is done so that the implementation is as forgiving as
* possible of redundancy within cataloged index attributes (or, less
* usefully, within inference specification elements). If collations actually
* differ between apparently redundantly indexed attributes (redundant within
* or across indexes), then there really is no redundancy as such.
*
* Note that if an inference element specifies an opclass and a collation at
* once, both must match in at least one particular attribute within index
* catalog definition in order for that inference element to be considered
* inferred/satisfied.
*/
static bool
infer_collation_opclass_match(InferenceElem *elem, Relation idxRel,
List *idxExprs)
{
AttrNumber natt;
Oid inferopfamily = InvalidOid; /* OID of opclass opfamily */
Oid inferopcinputtype = InvalidOid; /* OID of opclass input type */
int nplain = 0; /* # plain attrs observed */
/*
* If inference specification element lacks collation/opclass, then no
* need to check for exact match.
*/
if (elem->infercollid == InvalidOid && elem->inferopclass == InvalidOid)
return true;
/*
* Lookup opfamily and input type, for matching indexes
*/
if (elem->inferopclass)
{
inferopfamily = get_opclass_family(elem->inferopclass);
inferopcinputtype = get_opclass_input_type(elem->inferopclass);
}
for (natt = 1; natt <= idxRel->rd_att->natts; natt++)
{
Oid opfamily = idxRel->rd_opfamily[natt - 1];
Oid opcinputtype = idxRel->rd_opcintype[natt - 1];
Oid collation = idxRel->rd_indcollation[natt - 1];
int attno = idxRel->rd_index->indkey.values[natt - 1];
if (attno != 0)
nplain++;
if (elem->inferopclass != InvalidOid &&
(inferopfamily != opfamily || inferopcinputtype != opcinputtype))
{
/* Attribute needed to match opclass, but didn't */
continue;
}
if (elem->infercollid != InvalidOid &&
elem->infercollid != collation)
{
/* Attribute needed to match collation, but didn't */
continue;
}
/* If one matching index att found, good enough -- return true */
if (IsA(elem->expr, Var))
{
if (((Var *) elem->expr)->varattno == attno)
return true;
}
else if (attno == 0)
{
Node *nattExpr = list_nth(idxExprs, (natt - 1) - nplain);
/*
* Note that unlike routines like match_index_to_operand() we
* don't need to care about RelabelType. Neither the index
* definition nor the inference clause should contain them.
*/
if (equal(elem->expr, nattExpr))
return true;
}
}
return false;
}
/*
* estimate_rel_size - estimate # pages and # tuples in a table or index
*
* We also estimate the fraction of the pages that are marked all-visible in
* the visibility map, for use in estimation of index-only scans.
*
* If attr_widths isn't NULL, it points to the zero-index entry of the
* relation's attr_widths[] cache; we fill this in if we have need to compute
* the attribute widths for estimation purposes.
*/
void
estimate_rel_size(Relation rel, int32 *attr_widths,
BlockNumber *pages, double *tuples, double *allvisfrac)
{
BlockNumber curpages;
BlockNumber relpages;
double reltuples;
BlockNumber relallvisible;
double density;
switch (rel->rd_rel->relkind)
{
case RELKIND_RELATION:
case RELKIND_INDEX:
case RELKIND_MATVIEW:
case RELKIND_TOASTVALUE:
/* it has storage, ok to call the smgr */
curpages = RelationGetNumberOfBlocks(rel);
/*
* HACK: if the relation has never yet been vacuumed, use a
* minimum size estimate of 10 pages. The idea here is to avoid
* assuming a newly-created table is really small, even if it
* currently is, because that may not be true once some data gets
* loaded into it. Once a vacuum or analyze cycle has been done
* on it, it's more reasonable to believe the size is somewhat
* stable.
*
* (Note that this is only an issue if the plan gets cached and
* used again after the table has been filled. What we're trying
* to avoid is using a nestloop-type plan on a table that has
* grown substantially since the plan was made. Normally,
* autovacuum/autoanalyze will occur once enough inserts have
* happened and cause cached-plan invalidation; but that doesn't
* happen instantaneously, and it won't happen at all for cases
* such as temporary tables.)
*
* We approximate "never vacuumed" by "has relpages = 0", which
* means this will also fire on genuinely empty relations. Not
* great, but fortunately that's a seldom-seen case in the real
* world, and it shouldn't degrade the quality of the plan too
* much anyway to err in this direction.
*
* There are two exceptions wherein we don't apply this heuristic.
* One is if the table has inheritance children. Totally empty
* parent tables are quite common, so we should be willing to
* believe that they are empty. Also, we don't apply the 10-page
* minimum to indexes.
*/
if (curpages < 10 &&
rel->rd_rel->relpages == 0 &&
!rel->rd_rel->relhassubclass &&
rel->rd_rel->relkind != RELKIND_INDEX)
curpages = 10;
/* report estimated # pages */
*pages = curpages;
/* quick exit if rel is clearly empty */
if (curpages == 0)
{
*tuples = 0;
*allvisfrac = 0;
break;
}
/* coerce values in pg_class to more desirable types */
relpages = (BlockNumber) rel->rd_rel->relpages;
reltuples = (double) rel->rd_rel->reltuples;
relallvisible = (BlockNumber) rel->rd_rel->relallvisible;
/*
* If it's an index, discount the metapage while estimating the
* number of tuples. This is a kluge because it assumes more than
* it ought to about index structure. Currently it's OK for
* btree, hash, and GIN indexes but suspect for GiST indexes.
*/
if (rel->rd_rel->relkind == RELKIND_INDEX &&
relpages > 0)
{
curpages--;
relpages--;
}
/* estimate number of tuples from previous tuple density */
if (relpages > 0)
density = reltuples / (double) relpages;
else
{
/*
* When we have no data because the relation was truncated,
* estimate tuple width from attribute datatypes. We assume
* here that the pages are completely full, which is OK for
* tables (since they've presumably not been VACUUMed yet) but
* is probably an overestimate for indexes. Fortunately
* get_relation_info() can clamp the overestimate to the
* parent table's size.
*
* Note: this code intentionally disregards alignment
* considerations, because (a) that would be gilding the lily
* considering how crude the estimate is, and (b) it creates
* platform dependencies in the default plans which are kind
* of a headache for regression testing.
*/
int32 tuple_width;
tuple_width = get_rel_data_width(rel, attr_widths);
tuple_width += MAXALIGN(SizeofHeapTupleHeader);
tuple_width += sizeof(ItemIdData);
/* note: integer division is intentional here */
density = (BLCKSZ - SizeOfPageHeaderData) / tuple_width;
}
*tuples = rint(density * (double) curpages);
/*
* We use relallvisible as-is, rather than scaling it up like we
* do for the pages and tuples counts, on the theory that any
* pages added since the last VACUUM are most likely not marked
* all-visible. But costsize.c wants it converted to a fraction.
*/
if (relallvisible == 0 || curpages <= 0)
*allvisfrac = 0;
else if ((double) relallvisible >= curpages)
*allvisfrac = 1;
else
*allvisfrac = (double) relallvisible / curpages;
break;
case RELKIND_SEQUENCE:
/* Sequences always have a known size */
*pages = 1;
*tuples = 1;
*allvisfrac = 0;
break;
case RELKIND_FOREIGN_TABLE:
/* Just use whatever's in pg_class */
*pages = rel->rd_rel->relpages;
*tuples = rel->rd_rel->reltuples;
*allvisfrac = 0;
break;
default:
/* else it has no disk storage; probably shouldn't get here? */
*pages = 0;
*tuples = 0;
*allvisfrac = 0;
break;
}
}
/*
* get_rel_data_width
*
* Estimate the average width of (the data part of) the relation's tuples.
*
* If attr_widths isn't NULL, it points to the zero-index entry of the
* relation's attr_widths[] cache; use and update that cache as appropriate.
*
* Currently we ignore dropped columns. Ideally those should be included
* in the result, but we haven't got any way to get info about them; and
* since they might be mostly NULLs, treating them as zero-width is not
* necessarily the wrong thing anyway.
*/
static int32
get_rel_data_width(Relation rel, int32 *attr_widths)
{
int32 tuple_width = 0;
int i;
for (i = 1; i <= RelationGetNumberOfAttributes(rel); i++)
{
Form_pg_attribute att = TupleDescAttr(rel->rd_att, i - 1);
int32 item_width;
if (att->attisdropped)
continue;
/* use previously cached data, if any */
if (attr_widths != NULL && attr_widths[i] > 0)
{
tuple_width += attr_widths[i];
continue;
}
/* This should match set_rel_width() in costsize.c */
item_width = get_attavgwidth(RelationGetRelid(rel), i);
if (item_width <= 0)
{
item_width = get_typavgwidth(att->atttypid, att->atttypmod);
Assert(item_width > 0);
}
if (attr_widths != NULL)
attr_widths[i] = item_width;
tuple_width += item_width;
}
return tuple_width;
}
/*
* get_relation_data_width
*
* External API for get_rel_data_width: same behavior except we have to
* open the relcache entry.
*/
int32
get_relation_data_width(Oid relid, int32 *attr_widths)
{
int32 result;
Relation relation;
/* As above, assume relation is already locked */
relation = heap_open(relid, NoLock);
result = get_rel_data_width(relation, attr_widths);
heap_close(relation, NoLock);
return result;
}
/*
* get_relation_constraints
*
* Retrieve the validated CHECK constraint expressions of the given relation.
*
* Returns a List (possibly empty) of constraint expressions. Each one
* has been canonicalized, and its Vars are changed to have the varno
* indicated by rel->relid. This allows the expressions to be easily
* compared to expressions taken from WHERE.
*
* If include_notnull is true, "col IS NOT NULL" expressions are generated
* and added to the result for each column that's marked attnotnull.
*
* Note: at present this is invoked at most once per relation per planner
* run, and in many cases it won't be invoked at all, so there seems no
* point in caching the data in RelOptInfo.
*/
static List *
get_relation_constraints(PlannerInfo *root,
Oid relationObjectId, RelOptInfo *rel,
bool include_notnull)
{
List *result = NIL;
Index varno = rel->relid;
Relation relation;
TupleConstr *constr;
List *pcqual;
/*
* We assume the relation has already been safely locked.
*/
relation = heap_open(relationObjectId, NoLock);
constr = relation->rd_att->constr;
if (constr != NULL)
{
int num_check = constr->num_check;
int i;
for (i = 0; i < num_check; i++)
{
Node *cexpr;
/*
* If this constraint hasn't been fully validated yet, we must
* ignore it here.
*/
if (!constr->check[i].ccvalid)
continue;
cexpr = stringToNode(constr->check[i].ccbin);
/*
* Run each expression through const-simplification and
* canonicalization. This is not just an optimization, but is
* necessary, because we will be comparing it to
* similarly-processed qual clauses, and may fail to detect valid
* matches without this. This must match the processing done to
* qual clauses in preprocess_expression()! (We can skip the
* stuff involving subqueries, however, since we don't allow any
* in check constraints.)
*/
cexpr = eval_const_expressions(root, cexpr);
cexpr = (Node *) canonicalize_qual((Expr *) cexpr);
/* Fix Vars to have the desired varno */
if (varno != 1)
ChangeVarNodes(cexpr, 1, varno, 0);
/*
* Finally, convert to implicit-AND format (that is, a List) and
* append the resulting item(s) to our output list.
*/
result = list_concat(result,
make_ands_implicit((Expr *) cexpr));
}
/* Add NOT NULL constraints in expression form, if requested */
if (include_notnull && constr->has_not_null)
{
int natts = relation->rd_att->natts;
for (i = 1; i <= natts; i++)
{
Form_pg_attribute att = TupleDescAttr(relation->rd_att, i - 1);
if (att->attnotnull && !att->attisdropped)
{
NullTest *ntest = makeNode(NullTest);
ntest->arg = (Expr *) makeVar(varno,
i,
att->atttypid,
att->atttypmod,
att->attcollation,
0);
ntest->nulltesttype = IS_NOT_NULL;
/*
* argisrow=false is correct even for a composite column,
* because attnotnull does not represent a SQL-spec IS NOT
* NULL test in such a case, just IS DISTINCT FROM NULL.
*/
ntest->argisrow = false;
ntest->location = -1;
result = lappend(result, ntest);
}
}
}
}
/* Append partition predicates, if any */
pcqual = RelationGetPartitionQual(relation);
if (pcqual)
{
/*
* Run each expression through const-simplification and
* canonicalization similar to check constraints.
*/
pcqual = (List *) eval_const_expressions(root, (Node *) pcqual);
pcqual = (List *) canonicalize_qual((Expr *) pcqual);
/* Fix Vars to have the desired varno */
if (varno != 1)
ChangeVarNodes((Node *) pcqual, 1, varno, 0);
result = list_concat(result, pcqual);
}
heap_close(relation, NoLock);
return result;
}
/*
* get_relation_statistics
* Retrieve extended statistics defined on the table.
*
* Returns a List (possibly empty) of StatisticExtInfo objects describing
* the statistics. Note that this doesn't load the actual statistics data,
* just the identifying metadata. Only stats actually built are considered.
*/
static List *
get_relation_statistics(RelOptInfo *rel, Relation relation)
{
List *statoidlist;
List *stainfos = NIL;
ListCell *l;
statoidlist = RelationGetStatExtList(relation);
foreach(l, statoidlist)
{
Oid statOid = lfirst_oid(l);
Form_pg_statistic_ext staForm;
HeapTuple htup;
Bitmapset *keys = NULL;
int i;
htup = SearchSysCache1(STATEXTOID, ObjectIdGetDatum(statOid));
if (!htup)
elog(ERROR, "cache lookup failed for statistics object %u", statOid);
staForm = (Form_pg_statistic_ext) GETSTRUCT(htup);
/*
* First, build the array of columns covered. This is ultimately
* wasted if no stats within the object have actually been built, but
* it doesn't seem worth troubling over that case.
*/
for (i = 0; i < staForm->stxkeys.dim1; i++)
keys = bms_add_member(keys, staForm->stxkeys.values[i]);
/* add one StatisticExtInfo for each kind built */
if (statext_is_kind_built(htup, STATS_EXT_NDISTINCT))
{
StatisticExtInfo *info = makeNode(StatisticExtInfo);
info->statOid = statOid;
info->rel = rel;
info->kind = STATS_EXT_NDISTINCT;
info->keys = bms_copy(keys);
stainfos = lcons(info, stainfos);
}
if (statext_is_kind_built(htup, STATS_EXT_DEPENDENCIES))
{
StatisticExtInfo *info = makeNode(StatisticExtInfo);
info->statOid = statOid;
info->rel = rel;
info->kind = STATS_EXT_DEPENDENCIES;
info->keys = bms_copy(keys);
stainfos = lcons(info, stainfos);
}
ReleaseSysCache(htup);
bms_free(keys);
}
list_free(statoidlist);
return stainfos;
}
/*
* relation_excluded_by_constraints
*
* Detect whether the relation need not be scanned because it has either
* self-inconsistent restrictions, or restrictions inconsistent with the
* relation's validated CHECK constraints.
*
* Note: this examines only rel->relid, rel->reloptkind, and
* rel->baserestrictinfo; therefore it can be called before filling in
* other fields of the RelOptInfo.
*/
bool
relation_excluded_by_constraints(PlannerInfo *root,
RelOptInfo *rel, RangeTblEntry *rte)
{
List *safe_restrictions;
List *constraint_pred;
List *safe_constraints;
ListCell *lc;
/* As of now, constraint exclusion works only with simple relations. */
Assert(IS_SIMPLE_REL(rel));
/*
* Regardless of the setting of constraint_exclusion, detect
* constant-FALSE-or-NULL restriction clauses. Because const-folding will
* reduce "anything AND FALSE" to just "FALSE", any such case should
* result in exactly one baserestrictinfo entry. This doesn't fire very
* often, but it seems cheap enough to be worth doing anyway. (Without
* this, we'd miss some optimizations that 9.5 and earlier found via much
* more roundabout methods.)
*/
if (list_length(rel->baserestrictinfo) == 1)
{
RestrictInfo *rinfo = (RestrictInfo *) linitial(rel->baserestrictinfo);
Expr *clause = rinfo->clause;
if (clause && IsA(clause, Const) &&
(((Const *) clause)->constisnull ||
!DatumGetBool(((Const *) clause)->constvalue)))
return true;
}
/* Skip further tests if constraint exclusion is disabled for the rel */
if (constraint_exclusion == CONSTRAINT_EXCLUSION_OFF ||
(constraint_exclusion == CONSTRAINT_EXCLUSION_PARTITION &&
!(rel->reloptkind == RELOPT_OTHER_MEMBER_REL ||
(root->hasInheritedTarget &&
rel->reloptkind == RELOPT_BASEREL &&
rel->relid == root->parse->resultRelation))))
return false;
/*
* Check for self-contradictory restriction clauses. We dare not make
* deductions with non-immutable functions, but any immutable clauses that
* are self-contradictory allow us to conclude the scan is unnecessary.
*
* Note: strip off RestrictInfo because predicate_refuted_by() isn't
* expecting to see any in its predicate argument.
*/
safe_restrictions = NIL;
foreach(lc, rel->baserestrictinfo)
{
RestrictInfo *rinfo = (RestrictInfo *) lfirst(lc);
if (!contain_mutable_functions((Node *) rinfo->clause))
safe_restrictions = lappend(safe_restrictions, rinfo->clause);
}
if (predicate_refuted_by(safe_restrictions, safe_restrictions, false))
return true;
/*
* Only plain relations have constraints. In a partitioning hierarchy,
* but not with regular table inheritance, it's OK to assume that any
* constraints that hold for the parent also hold for every child; for
* instance, table inheritance allows the parent to have constraints
* marked NO INHERIT, but table partitioning does not. We choose to check
* whether the partitioning parents can be excluded here; doing so
* consumes some cycles, but potentially saves us the work of excluding
* each child individually.
*/
if (rte->rtekind != RTE_RELATION ||
(rte->inh && rte->relkind != RELKIND_PARTITIONED_TABLE))
return false;
/*
* OK to fetch the constraint expressions. Include "col IS NOT NULL"
* expressions for attnotnull columns, in case we can refute those.
*/
constraint_pred = get_relation_constraints(root, rte->relid, rel, true);
/*
* We do not currently enforce that CHECK constraints contain only
* immutable functions, so it's necessary to check here. We daren't draw
* conclusions from plan-time evaluation of non-immutable functions. Since
* they're ANDed, we can just ignore any mutable constraints in the list,
* and reason about the rest.
*/
safe_constraints = NIL;
foreach(lc, constraint_pred)
{
Node *pred = (Node *) lfirst(lc);
if (!contain_mutable_functions(pred))
safe_constraints = lappend(safe_constraints, pred);
}
/*
* The constraints are effectively ANDed together, so we can just try to
* refute the entire collection at once. This may allow us to make proofs
* that would fail if we took them individually.
*
* Note: we use rel->baserestrictinfo, not safe_restrictions as might seem
* an obvious optimization. Some of the clauses might be OR clauses that
* have volatile and nonvolatile subclauses, and it's OK to make
* deductions with the nonvolatile parts.
*/
if (predicate_refuted_by(safe_constraints, rel->baserestrictinfo, false))
return true;
return false;
}
/*
* build_physical_tlist
*
* Build a targetlist consisting of exactly the relation's user attributes,
* in order. The executor can special-case such tlists to avoid a projection
* step at runtime, so we use such tlists preferentially for scan nodes.
*
* Exception: if there are any dropped columns, we punt and return NIL.
* Ideally we would like to handle the dropped-column case too. However this
* creates problems for ExecTypeFromTL, which may be asked to build a tupdesc
* for a tlist that includes vars of no-longer-existent types. In theory we
* could dig out the required info from the pg_attribute entries of the
* relation, but that data is not readily available to ExecTypeFromTL.
* For now, we don't apply the physical-tlist optimization when there are
* dropped cols.
*
* We also support building a "physical" tlist for subqueries, functions,
* values lists, table expressions, and CTEs, since the same optimization can
* occur in SubqueryScan, FunctionScan, ValuesScan, CteScan, TableFunc,
* NamedTuplestoreScan, and WorkTableScan nodes.
*/
List *
build_physical_tlist(PlannerInfo *root, RelOptInfo *rel)
{
List *tlist = NIL;
Index varno = rel->relid;
RangeTblEntry *rte = planner_rt_fetch(varno, root);
Relation relation;
Query *subquery;
Var *var;
ListCell *l;
int attrno,
numattrs;
List *colvars;
switch (rte->rtekind)
{
case RTE_RELATION:
/* Assume we already have adequate lock */
relation = heap_open(rte->relid, NoLock);
numattrs = RelationGetNumberOfAttributes(relation);
for (attrno = 1; attrno <= numattrs; attrno++)
{
Form_pg_attribute att_tup = TupleDescAttr(relation->rd_att,
attrno - 1);
if (att_tup->attisdropped)
{
/* found a dropped col, so punt */
tlist = NIL;
break;
}
var = makeVar(varno,
attrno,
att_tup->atttypid,
att_tup->atttypmod,
att_tup->attcollation,
0);
tlist = lappend(tlist,
makeTargetEntry((Expr *) var,
attrno,
NULL,
false));
}
heap_close(relation, NoLock);
break;
case RTE_SUBQUERY:
subquery = rte->subquery;
foreach(l, subquery->targetList)
{
TargetEntry *tle = (TargetEntry *) lfirst(l);
/*
* A resjunk column of the subquery can be reflected as
* resjunk in the physical tlist; we need not punt.
*/
var = makeVarFromTargetEntry(varno, tle);
tlist = lappend(tlist,
makeTargetEntry((Expr *) var,
tle->resno,
NULL,
tle->resjunk));
}
break;
case RTE_FUNCTION:
case RTE_TABLEFUNC:
case RTE_VALUES:
case RTE_CTE:
case RTE_NAMEDTUPLESTORE:
/* Not all of these can have dropped cols, but share code anyway */
expandRTE(rte, varno, 0, -1, true /* include dropped */ ,
NULL, &colvars);
foreach(l, colvars)
{
var = (Var *) lfirst(l);
/*
* A non-Var in expandRTE's output means a dropped column;
* must punt.
*/
if (!IsA(var, Var))
{
tlist = NIL;
break;
}
tlist = lappend(tlist,
makeTargetEntry((Expr *) var,
var->varattno,
NULL,
false));
}
break;
default:
/* caller error */
elog(ERROR, "unsupported RTE kind %d in build_physical_tlist",
(int) rte->rtekind);
break;
}
return tlist;
}
/*
* build_index_tlist
*
* Build a targetlist representing the columns of the specified index.
* Each column is represented by a Var for the corresponding base-relation
* column, or an expression in base-relation Vars, as appropriate.
*
* There are never any dropped columns in indexes, so unlike
* build_physical_tlist, we need no failure case.
*/
static List *
build_index_tlist(PlannerInfo *root, IndexOptInfo *index,
Relation heapRelation)
{
List *tlist = NIL;
Index varno = index->rel->relid;
ListCell *indexpr_item;
int i;
indexpr_item = list_head(index->indexprs);
for (i = 0; i < index->ncolumns; i++)
{
int indexkey = index->indexkeys[i];
Expr *indexvar;
if (indexkey != 0)
{
/* simple column */
Form_pg_attribute att_tup;
if (indexkey < 0)
att_tup = SystemAttributeDefinition(indexkey,
heapRelation->rd_rel->relhasoids);
else
att_tup = TupleDescAttr(heapRelation->rd_att, indexkey - 1);
indexvar = (Expr *) makeVar(varno,
indexkey,
att_tup->atttypid,
att_tup->atttypmod,
att_tup->attcollation,
0);
}
else
{
/* expression column */
if (indexpr_item == NULL)
elog(ERROR, "wrong number of index expressions");
indexvar = (Expr *) lfirst(indexpr_item);
indexpr_item = lnext(indexpr_item);
}
tlist = lappend(tlist,
makeTargetEntry(indexvar,
i + 1,
NULL,
false));
}
if (indexpr_item != NULL)
elog(ERROR, "wrong number of index expressions");
return tlist;
}
/*
* restriction_selectivity
*
* Returns the selectivity of a specified restriction operator clause.
* This code executes registered procedures stored in the
* operator relation, by calling the function manager.
*
* See clause_selectivity() for the meaning of the additional parameters.
*/
Selectivity
restriction_selectivity(PlannerInfo *root,
Oid operatorid,
List *args,
Oid inputcollid,
int varRelid)
{
RegProcedure oprrest = get_oprrest(operatorid);
float8 result;
/*
* if the oprrest procedure is missing for whatever reason, use a
* selectivity of 0.5
*/
if (!oprrest)
return (Selectivity) 0.5;
result = DatumGetFloat8(OidFunctionCall4Coll(oprrest,
inputcollid,
PointerGetDatum(root),
ObjectIdGetDatum(operatorid),
PointerGetDatum(args),
Int32GetDatum(varRelid)));
if (result < 0.0 || result > 1.0)
elog(ERROR, "invalid restriction selectivity: %f", result);
return (Selectivity) result;
}
/*
* join_selectivity
*
* Returns the selectivity of a specified join operator clause.
* This code executes registered procedures stored in the
* operator relation, by calling the function manager.
*/
Selectivity
join_selectivity(PlannerInfo *root,
Oid operatorid,
List *args,
Oid inputcollid,
JoinType jointype,
SpecialJoinInfo *sjinfo)
{
RegProcedure oprjoin = get_oprjoin(operatorid);
float8 result;
/*
* if the oprjoin procedure is missing for whatever reason, use a
* selectivity of 0.5
*/
if (!oprjoin)
return (Selectivity) 0.5;
result = DatumGetFloat8(OidFunctionCall5Coll(oprjoin,
inputcollid,
PointerGetDatum(root),
ObjectIdGetDatum(operatorid),
PointerGetDatum(args),
Int16GetDatum(jointype),
PointerGetDatum(sjinfo)));
if (result < 0.0 || result > 1.0)
elog(ERROR, "invalid join selectivity: %f", result);
return (Selectivity) result;
}
/*
* has_unique_index
*
* Detect whether there is a unique index on the specified attribute
* of the specified relation, thus allowing us to conclude that all
* the (non-null) values of the attribute are distinct.
*
* This function does not check the index's indimmediate property, which
* means that uniqueness may transiently fail to hold intra-transaction.
* That's appropriate when we are making statistical estimates, but beware
* of using this for any correctness proofs.
*/
bool
has_unique_index(RelOptInfo *rel, AttrNumber attno)
{
ListCell *ilist;
foreach(ilist, rel->indexlist)
{
IndexOptInfo *index = (IndexOptInfo *) lfirst(ilist);
/*
* Note: ignore partial indexes, since they don't allow us to conclude
* that all attr values are distinct, *unless* they are marked predOK
* which means we know the index's predicate is satisfied by the
* query. We don't take any interest in expressional indexes either.
* Also, a multicolumn unique index doesn't allow us to conclude that
* just the specified attr is unique.
*/
if (index->unique &&
index->ncolumns == 1 &&
index->indexkeys[0] == attno &&
(index->indpred == NIL || index->predOK))
return true;
}
return false;
}
/*
* has_row_triggers
*
* Detect whether the specified relation has any row-level triggers for event.
*/
bool
has_row_triggers(PlannerInfo *root, Index rti, CmdType event)
{
RangeTblEntry *rte = planner_rt_fetch(rti, root);
Relation relation;
TriggerDesc *trigDesc;
bool result = false;
/* Assume we already have adequate lock */
relation = heap_open(rte->relid, NoLock);
trigDesc = relation->trigdesc;
switch (event)
{
case CMD_INSERT:
if (trigDesc &&
(trigDesc->trig_insert_after_row ||
trigDesc->trig_insert_before_row))
result = true;
break;
case CMD_UPDATE:
if (trigDesc &&
(trigDesc->trig_update_after_row ||
trigDesc->trig_update_before_row))
result = true;
break;
case CMD_DELETE:
if (trigDesc &&
(trigDesc->trig_delete_after_row ||
trigDesc->trig_delete_before_row))
result = true;
break;
default:
elog(ERROR, "unrecognized CmdType: %d", (int) event);
break;
}
heap_close(relation, NoLock);
return result;
}
/*
* set_relation_partition_info
*
* Set partitioning scheme and related information for a partitioned table.
*/
static void
set_relation_partition_info(PlannerInfo *root, RelOptInfo *rel,
Relation relation)
{
PartitionDesc partdesc;
PartitionKey partkey;
Assert(relation->rd_rel->relkind == RELKIND_PARTITIONED_TABLE);
partdesc = RelationGetPartitionDesc(relation);
partkey = RelationGetPartitionKey(relation);
rel->part_scheme = find_partition_scheme(root, relation);
Assert(partdesc != NULL && rel->part_scheme != NULL);
rel->boundinfo = partition_bounds_copy(partdesc->boundinfo, partkey);
rel->nparts = partdesc->nparts;
set_baserel_partition_key_exprs(relation, rel);
}
/*
* find_partition_scheme
*
* Find or create a PartitionScheme for this Relation.
*/
static PartitionScheme
find_partition_scheme(PlannerInfo *root, Relation relation)
{
PartitionKey partkey = RelationGetPartitionKey(relation);
ListCell *lc;
int partnatts;
PartitionScheme part_scheme;
/* A partitioned table should have a partition key. */
Assert(partkey != NULL);
partnatts = partkey->partnatts;
/* Search for a matching partition scheme and return if found one. */
foreach(lc, root->part_schemes)
{
part_scheme = lfirst(lc);
/* Match partitioning strategy and number of keys. */
if (partkey->strategy != part_scheme->strategy ||
partnatts != part_scheme->partnatts)
continue;
/* Match the partition key types. */
if (memcmp(partkey->partopfamily, part_scheme->partopfamily,
sizeof(Oid) * partnatts) != 0 ||
memcmp(partkey->partopcintype, part_scheme->partopcintype,
sizeof(Oid) * partnatts) != 0 ||
memcmp(partkey->parttypcoll, part_scheme->parttypcoll,
sizeof(Oid) * partnatts) != 0)
continue;
/*
* Length and byval information should match when partopcintype
* matches.
*/
Assert(memcmp(partkey->parttyplen, part_scheme->parttyplen,
sizeof(int16) * partnatts) == 0);
Assert(memcmp(partkey->parttypbyval, part_scheme->parttypbyval,
sizeof(bool) * partnatts) == 0);
/* Found matching partition scheme. */
return part_scheme;
}
/*
* Did not find matching partition scheme. Create one copying relevant
* information from the relcache. We need to copy the contents of the
* array since the relcache entry may not survive after we have closed the
* relation.
*/
part_scheme = (PartitionScheme) palloc0(sizeof(PartitionSchemeData));
part_scheme->strategy = partkey->strategy;
part_scheme->partnatts = partkey->partnatts;
part_scheme->partopfamily = (Oid *) palloc(sizeof(Oid) * partnatts);
memcpy(part_scheme->partopfamily, partkey->partopfamily,
sizeof(Oid) * partnatts);
part_scheme->partopcintype = (Oid *) palloc(sizeof(Oid) * partnatts);
memcpy(part_scheme->partopcintype, partkey->partopcintype,
sizeof(Oid) * partnatts);
part_scheme->parttypcoll = (Oid *) palloc(sizeof(Oid) * partnatts);
memcpy(part_scheme->parttypcoll, partkey->parttypcoll,
sizeof(Oid) * partnatts);
part_scheme->parttyplen = (int16 *) palloc(sizeof(int16) * partnatts);
memcpy(part_scheme->parttyplen, partkey->parttyplen,
sizeof(int16) * partnatts);
part_scheme->parttypbyval = (bool *) palloc(sizeof(bool) * partnatts);
memcpy(part_scheme->parttypbyval, partkey->parttypbyval,
sizeof(bool) * partnatts);
/* Add the partitioning scheme to PlannerInfo. */
root->part_schemes = lappend(root->part_schemes, part_scheme);
return part_scheme;
}
/*
* set_baserel_partition_key_exprs
*
* Builds partition key expressions for the given base relation and sets them
* in given RelOptInfo. Any single column partition keys are converted to Var
* nodes. All Var nodes are restamped with the relid of given relation.
*/
static void
set_baserel_partition_key_exprs(Relation relation,
RelOptInfo *rel)
{
PartitionKey partkey = RelationGetPartitionKey(relation);
int partnatts;
int cnt;
List **partexprs;
ListCell *lc;
Index varno = rel->relid;
Assert(IS_SIMPLE_REL(rel) && rel->relid > 0);
/* A partitioned table should have a partition key. */
Assert(partkey != NULL);
partnatts = partkey->partnatts;
partexprs = (List **) palloc(sizeof(List *) * partnatts);
lc = list_head(partkey->partexprs);
for (cnt = 0; cnt < partnatts; cnt++)
{
Expr *partexpr;
AttrNumber attno = partkey->partattrs[cnt];
if (attno != InvalidAttrNumber)
{
/* Single column partition key is stored as a Var node. */
Assert(attno > 0);
partexpr = (Expr *) makeVar(varno, attno,
partkey->parttypid[cnt],
partkey->parttypmod[cnt],
partkey->parttypcoll[cnt], 0);
}
else
{
if (lc == NULL)
elog(ERROR, "wrong number of partition key expressions");
/* Re-stamp the expression with given varno. */
partexpr = (Expr *) copyObject(lfirst(lc));
ChangeVarNodes((Node *) partexpr, 1, varno, 0);
lc = lnext(lc);
}
partexprs[cnt] = list_make1(partexpr);
}
rel->partexprs = partexprs;
/*
* A base relation can not have nullable partition key expressions. We
* still allocate array of empty expressions lists to keep partition key
* expression handling code simple. See build_joinrel_partition_info() and
* match_expr_to_partition_keys().
*/
rel->nullable_partexprs = (List **) palloc0(sizeof(List *) * partnatts);
}
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