/// Extract a sorted de-duped vector of all the bound parameter indexes in a plan. Or null if // none. public int[] boundParamIndexes() { if (parameters.length == 0) { return null; } BitSet ints = new BitSet(); ArrayList<AbstractPlanNode> ixscans = rootPlanGraph.findAllNodesOfType(PlanNodeType.INDEXSCAN); if (subPlanGraph != null) { ixscans.addAll(subPlanGraph.findAllNodesOfType(PlanNodeType.INDEXSCAN)); } for (AbstractPlanNode apn : ixscans) { assert (apn instanceof IndexScanPlanNode); IndexScanPlanNode ixs = (IndexScanPlanNode) apn; setParamIndexes(ints, ixs.getBindings()); } ArrayList<AbstractPlanNode> ixcounts = rootPlanGraph.findAllNodesOfType(PlanNodeType.INDEXCOUNT); if (subPlanGraph != null) { ixcounts.addAll(subPlanGraph.findAllNodesOfType(PlanNodeType.INDEXCOUNT)); } for (AbstractPlanNode apn : ixcounts) { assert (apn instanceof IndexCountPlanNode); IndexCountPlanNode ixc = (IndexCountPlanNode) apn; setParamIndexes(ints, ixc.getBindings()); } return bitSetToIntVector(ints); }
@Override protected AbstractPlanNode recursivelyApply(AbstractPlanNode plan) { assert (plan != null); // depth first: // find AggregatePlanNode with exactly one child // where that child is an AbstractScanPlanNode. // Replace any qualifying AggregatePlanNode / AbstractScanPlanNode pair // with an IndexCountPlanNode or TableCountPlanNode ArrayList<AbstractPlanNode> children = new ArrayList<AbstractPlanNode>(); for (int i = 0; i < plan.getChildCount(); i++) children.add(plan.getChild(i)); for (AbstractPlanNode child : children) { // TODO this will break when children feed multiple parents AbstractPlanNode newChild = recursivelyApply(child); // Do a graft into the (parent) plan only if a replacement for a child was found. if (newChild == child) { continue; } boolean replaced = plan.replaceChild(child, newChild); assert (true == replaced); } // check for an aggregation of the right form if ((plan instanceof AggregatePlanNode) == false) return plan; assert (plan.getChildCount() == 1); AggregatePlanNode aggplan = (AggregatePlanNode) plan; // ENG-6131 fixed here. if (!(aggplan.isTableCountStar() || aggplan.isTableNonDistinctCountConstant() || aggplan.isTableCountNonDistinctNullableColumn())) { return plan; } AbstractPlanNode child = plan.getChild(0); // A table count can replace a seq scan only if it has no predicates. if (child instanceof SeqScanPlanNode) { if (((SeqScanPlanNode) child).getPredicate() != null) { return plan; } AbstractExpression postPredicate = aggplan.getPostPredicate(); if (postPredicate != null) { List<AbstractExpression> aggList = postPredicate.findAllSubexpressionsOfClass(AggregateExpression.class); boolean allCountStar = true; for (AbstractExpression expr : aggList) { if (expr.getExpressionType() != ExpressionType.AGGREGATE_COUNT_STAR) { allCountStar = false; break; } } if (allCountStar) { return plan; } } if (hasInlineLimit(aggplan)) { // table count EE executor does not handle inline limit stuff return plan; } return new TableCountPlanNode((AbstractScanPlanNode) child, aggplan); } // Otherwise, optimized counts only replace particular cases of index scan. if ((child instanceof IndexScanPlanNode) == false) return plan; IndexScanPlanNode isp = (IndexScanPlanNode) child; // Guard against (possible future?) cases of indexable subquery. if (((IndexScanPlanNode) child).isSubQuery()) { return plan; } // An index count or table count can replace an index scan only if it has no (post-)predicates // except those (post-)predicates are artifact predicates we added for reverse scan purpose only if (isp.getPredicate() != null && !isp.isPredicatesOptimizableForAggregate()) { return plan; } // With no start or end keys, there's not much a counting index can do. if (isp.getEndExpression() == null && isp.getSearchKeyExpressions().size() == 0) { // An indexed query without a where clause can fall back to a plain old table count. // This can only happen when a confused query like // "select count(*) from table order by index_key;" // meets a naive planner that doesn't just cull the no-op ORDER BY. Who, us? if (hasInlineLimit(aggplan)) { return plan; } return new TableCountPlanNode(isp, aggplan); } // check for the index's support for counting Index idx = isp.getCatalogIndex(); if (!idx.getCountable()) { return plan; } // The core idea is that counting index needs to know the start key and end key to // jump to to get counts instead of actually doing any scanning. // Options to be determined are: // - whether each of the start/end keys is missing, partial (a prefix of a compund key), or // complete, // - whether the count should include or exclude entries exactly matching each of the start/end // keys. // Not all combinations of these options are supported; // unsupportable cases cause the factory method to return null. IndexCountPlanNode countingPlan = IndexCountPlanNode.createOrNull(isp, aggplan); if (countingPlan == null) { return plan; } return countingPlan; }