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/*------------------------------------------------------------------------- * * plannodes.h * definitions for query plan nodes * * * Portions Copyright (c) 1996-2008, PostgreSQL Global Development Group * Portions Copyright (c) 1994, Regents of the University of California * * $PostgreSQL: pgsql/src/include/nodes/plannodes.h,v 1.99 2008/01/01 19:45:58 momjian Exp $ * *------------------------------------------------------------------------- */ #ifndef PLANNODES_H #define PLANNODES_H #include "access/sdir.h" #include "nodes/bitmapset.h" #include "nodes/primnodes.h" /* ---------------------------------------------------------------- * node definitions * ---------------------------------------------------------------- */ /* ---------------- * PlannedStmt node * * The output of the planner is a Plan tree headed by a PlannedStmt node. * PlannedStmt holds the "one time" information needed by the executor. * ---------------- */ typedef struct PlannedStmt { NodeTag type; CmdType commandType; /* select|insert|update|delete */ bool canSetTag; /* do I set the command result tag? */ bool transientPlan; /* redo plan when TransactionXmin changes? */ struct Plan *planTree; /* tree of Plan nodes */ List *rtable; /* list of RangeTblEntry nodes */ /* rtable indexes of target relations for INSERT/UPDATE/DELETE */ List *resultRelations; /* integer list of RT indexes, or NIL */ Node *utilityStmt; /* non-null if this is DECLARE CURSOR */ IntoClause *intoClause; /* target for SELECT INTO / CREATE TABLE AS */ List *subplans; /* Plan trees for SubPlan expressions */ Bitmapset *rewindPlanIDs; /* indices of subplans that require REWIND */ /* * If the query has a returningList then the planner will store a list of * processed targetlists (one per result relation) here. We must have a * separate RETURNING targetlist for each result rel because column * numbers may vary within an inheritance tree. In the targetlists, Vars * referencing the result relation will have their original varno and * varattno, while Vars referencing other rels will be converted to have * varno OUTER and varattno referencing a resjunk entry in the top plan * node's targetlist. */ List *returningLists; /* list of lists of TargetEntry, or NIL */ List *rowMarks; /* a list of RowMarkClause's */ List *relationOids; /* OIDs of relations the plan depends on */ int nParamExec; /* number of PARAM_EXEC Params used */ } PlannedStmt; /* macro for fetching the Plan associated with a SubPlan node */ #define exec_subplan_get_plan(plannedstmt, subplan) \ ((Plan *) list_nth((plannedstmt)->subplans, (subplan)->plan_id - 1)) /* ---------------- * Plan node * * All plan nodes "derive" from the Plan structure by having the * Plan structure as the first field. This ensures that everything works * when nodes are cast to Plan's. (node pointers are frequently cast to Plan* * when passed around generically in the executor) * * We never actually instantiate any Plan nodes; this is just the common * abstract superclass for all Plan-type nodes. * ---------------- */ typedef struct Plan { NodeTag type; /* * estimated execution costs for plan (see costsize.c for more info) */ Cost startup_cost; /* cost expended before fetching any tuples */ Cost total_cost; /* total cost (assuming all tuples fetched) */ /* * planner's estimate of result size of this plan step */ double plan_rows; /* number of rows plan is expected to emit */ int plan_width; /* average row width in bytes */ /* * Common structural data for all Plan types. */ List *targetlist; /* target list to be computed at this node */ List *qual; /* implicitly-ANDed qual conditions */ struct Plan *lefttree; /* input plan tree(s) */ struct Plan *righttree; List *initPlan; /* Init Plan nodes (un-correlated expr * subselects) */ /* * Information for management of parameter-change-driven rescanning * * extParam includes the paramIDs of all external PARAM_EXEC params * affecting this plan node or its children. setParam params from the * node's initPlans are not included, but their extParams are. * * allParam includes all the extParam paramIDs, plus the IDs of local * params that affect the node (i.e., the setParams of its initplans). * These are _all_ the PARAM_EXEC params that affect this node. */ Bitmapset *extParam; Bitmapset *allParam; } Plan; /* ---------------- * these are are defined to avoid confusion problems with "left" * and "right" and "inner" and "outer". The convention is that * the "left" plan is the "outer" plan and the "right" plan is * the inner plan, but these make the code more readable. * ---------------- */ #define innerPlan(node) (((Plan *)(node))->righttree) #define outerPlan(node) (((Plan *)(node))->lefttree) /* ---------------- * Result node - * If no outer plan, evaluate a variable-free targetlist. * If outer plan, return tuples from outer plan (after a level of * projection as shown by targetlist). * * If resconstantqual isn't NULL, it represents a one-time qualification * test (i.e., one that doesn't depend on any variables from the outer plan, * so needs to be evaluated only once). * ---------------- */ typedef struct Result { Plan plan; Node *resconstantqual; } Result; /* ---------------- * Append node - * Generate the concatenation of the results of sub-plans. * * Append nodes are sometimes used to switch between several result relations * (when the target of an UPDATE or DELETE is an inheritance set). Such a * node will have isTarget true. The Append executor is then responsible * for updating the executor state to point at the correct target relation * whenever it switches subplans. * ---------------- */ typedef struct Append { Plan plan; List *appendplans; bool isTarget; } Append; /* ---------------- * BitmapAnd node - * Generate the intersection of the results of sub-plans. * * The subplans must be of types that yield tuple bitmaps. The targetlist * and qual fields of the plan are unused and are always NIL. * ---------------- */ typedef struct BitmapAnd { Plan plan; List *bitmapplans; } BitmapAnd; /* ---------------- * BitmapOr node - * Generate the union of the results of sub-plans. * * The subplans must be of types that yield tuple bitmaps. The targetlist * and qual fields of the plan are unused and are always NIL. * ---------------- */ typedef struct BitmapOr { Plan plan; List *bitmapplans; } BitmapOr; /* * ========== * Scan nodes * ========== */ typedef struct Scan { Plan plan; Index scanrelid; /* relid is index into the range table */ } Scan; /* ---------------- * sequential scan node * ---------------- */ typedef Scan SeqScan; /* ---------------- * index scan node * * indexqualorig is an implicitly-ANDed list of index qual expressions, each * in the same form it appeared in the query WHERE condition. Each should * be of the form (indexkey OP comparisonval) or (comparisonval OP indexkey). * The indexkey is a Var or expression referencing column(s) of the index's * base table. The comparisonval might be any expression, but it won't use * any columns of the base table. * * indexqual has the same form, but the expressions have been commuted if * necessary to put the indexkeys on the left, and the indexkeys are replaced * by Var nodes identifying the index columns (varattno is the index column * position, not the base table's column, even though varno is for the base * table). This is a bit hokey ... would be cleaner to use a special-purpose * node type that could not be mistaken for a regular Var. But it will do * for now. * * indexstrategy and indexsubtype are lists corresponding one-to-one with * indexqual; they give information about the indexable operators that appear * at the top of each indexqual. * ---------------- */ typedef struct IndexScan { Scan scan; Oid indexid; /* OID of index to scan */ List *indexqual; /* list of index quals (OpExprs) */ List *indexqualorig; /* the same in original form */ List *indexstrategy; /* integer list of strategy numbers */ List *indexsubtype; /* OID list of strategy subtypes */ ScanDirection indexorderdir; /* forward or backward or don't care */ } IndexScan; /* ---------------- * bitmap index scan node * * BitmapIndexScan delivers a bitmap of potential tuple locations; * it does not access the heap itself. The bitmap is used by an * ancestor BitmapHeapScan node, possibly after passing through * intermediate BitmapAnd and/or BitmapOr nodes to combine it with * the results of other BitmapIndexScans. * * The fields have the same meanings as for IndexScan, except we don't * store a direction flag because direction is uninteresting. * * In a BitmapIndexScan plan node, the targetlist and qual fields are * not used and are always NIL. The indexqualorig field is unused at * run time too, but is saved for the benefit of EXPLAIN. * ---------------- */ typedef struct BitmapIndexScan { Scan scan; Oid indexid; /* OID of index to scan */ List *indexqual; /* list of index quals (OpExprs) */ List *indexqualorig; /* the same in original form */ List *indexstrategy; /* integer list of strategy numbers */ List *indexsubtype; /* OID list of strategy subtypes */ } BitmapIndexScan; /* ---------------- * bitmap sequential scan node * * This needs a copy of the qual conditions being used by the input index * scans because there are various cases where we need to recheck the quals; * for example, when the bitmap is lossy about the specific rows on a page * that meet the index condition. * ---------------- */ typedef struct BitmapHeapScan { Scan scan; List *bitmapqualorig; /* index quals, in standard expr form */ } BitmapHeapScan; /* ---------------- * tid scan node * * tidquals is an implicitly OR'ed list of qual expressions of the form * "CTID = pseudoconstant" or "CTID = ANY(pseudoconstant_array)". * ---------------- */ typedef struct TidScan { Scan scan; List *tidquals; /* qual(s) involving CTID = something */ } TidScan; /* ---------------- * subquery scan node * * SubqueryScan is for scanning the output of a sub-query in the range table. * We often need an extra plan node above the sub-query's plan to perform * expression evaluations (which we can't push into the sub-query without * risking changing its semantics). Although we are not scanning a physical * relation, we make this a descendant of Scan anyway for code-sharing * purposes. * * Note: we store the sub-plan in the type-specific subplan field, not in * the generic lefttree field as you might expect. This is because we do * not want plan-tree-traversal routines to recurse into the subplan without * knowing that they are changing Query contexts. * * Note: subrtable is used just to carry the subquery rangetable from * createplan.c to setrefs.c; it should always be NIL by the time the * executor sees the plan. * ---------------- */ typedef struct SubqueryScan { Scan scan; Plan *subplan; List *subrtable; /* temporary workspace for planner */ } SubqueryScan; /* ---------------- * FunctionScan node * ---------------- */ typedef struct FunctionScan { Scan scan; Node *funcexpr; /* expression tree for func call */ List *funccolnames; /* output column names (string Value nodes) */ List *funccoltypes; /* OID list of column type OIDs */ List *funccoltypmods; /* integer list of column typmods */ } FunctionScan; /* ---------------- * ValuesScan node * ---------------- */ typedef struct ValuesScan { Scan scan; List *values_lists; /* list of expression lists */ } ValuesScan; /* * ========== * Join nodes * ========== */ /* ---------------- * Join node * * jointype: rule for joining tuples from left and right subtrees * joinqual: qual conditions that came from JOIN/ON or JOIN/USING * (plan.qual contains conditions that came from WHERE) * * When jointype is INNER, joinqual and plan.qual are semantically * interchangeable. For OUTER jointypes, the two are *not* interchangeable; * only joinqual is used to determine whether a match has been found for * the purpose of deciding whether to generate null-extended tuples. * (But plan.qual is still applied before actually returning a tuple.) * For an outer join, only joinquals are allowed to be used as the merge * or hash condition of a merge or hash join. * ---------------- */ typedef struct Join { Plan plan; JoinType jointype; List *joinqual; /* JOIN quals (in addition to plan.qual) */ } Join; /* ---------------- * nest loop join node * ---------------- */ typedef struct NestLoop { Join join; } NestLoop; /* ---------------- * merge join node * * The expected ordering of each mergeable column is described by a btree * opfamily OID, a direction (BTLessStrategyNumber or BTGreaterStrategyNumber) * and a nulls-first flag. Note that the two sides of each mergeclause may * be of different datatypes, but they are ordered the same way according to * the common opfamily. The operator in each mergeclause must be an equality * operator of the indicated opfamily. * ---------------- */ typedef struct MergeJoin { Join join; List *mergeclauses; /* mergeclauses as expression trees */ /* these are arrays, but have the same length as the mergeclauses list: */ Oid *mergeFamilies; /* per-clause OIDs of btree opfamilies */ int *mergeStrategies; /* per-clause ordering (ASC or DESC) */ bool *mergeNullsFirst; /* per-clause nulls ordering */ } MergeJoin; /* ---------------- * hash join (probe) node * ---------------- */ typedef struct HashJoin { Join join; List *hashclauses; } HashJoin; /* ---------------- * materialization node * ---------------- */ typedef struct Material { Plan plan; } Material; /* ---------------- * sort node * ---------------- */ typedef struct Sort { Plan plan; int numCols; /* number of sort-key columns */ AttrNumber *sortColIdx; /* their indexes in the target list */ Oid *sortOperators; /* OIDs of operators to sort them by */ bool *nullsFirst; /* NULLS FIRST/LAST directions */ } Sort; /* --------------- * group node - * Used for queries with GROUP BY (but no aggregates) specified. * The input must be presorted according to the grouping columns. * --------------- */ typedef struct Group { Plan plan; int numCols; /* number of grouping columns */ AttrNumber *grpColIdx; /* their indexes in the target list */ Oid *grpOperators; /* equality operators to compare with */ } Group; /* --------------- * aggregate node * * An Agg node implements plain or grouped aggregation. For grouped * aggregation, we can work with presorted input or unsorted input; * the latter strategy uses an internal hashtable. * * Notice the lack of any direct info about the aggregate functions to be * computed. They are found by scanning the node's tlist and quals during * executor startup. (It is possible that there are no aggregate functions; * this could happen if they get optimized away by constant-folding, or if * we are using the Agg node to implement hash-based grouping.) * --------------- */ typedef enum AggStrategy { AGG_PLAIN, /* simple agg across all input rows */ AGG_SORTED, /* grouped agg, input must be sorted */ AGG_HASHED /* grouped agg, use internal hashtable */ } AggStrategy; typedef struct Agg { Plan plan; AggStrategy aggstrategy; int numCols; /* number of grouping columns */ AttrNumber *grpColIdx; /* their indexes in the target list */ Oid *grpOperators; /* equality operators to compare with */ long numGroups; /* estimated number of groups in input */ } Agg; /* ---------------- * unique node * ---------------- */ typedef struct Unique { Plan plan; int numCols; /* number of columns to check for uniqueness */ AttrNumber *uniqColIdx; /* their indexes in the target list */ Oid *uniqOperators; /* equality operators to compare with */ } Unique; /* ---------------- * hash build node * ---------------- */ typedef struct Hash { Plan plan; /* all other info is in the parent HashJoin node */ } Hash; /* ---------------- * setop node * ---------------- */ typedef enum SetOpCmd { SETOPCMD_INTERSECT, SETOPCMD_INTERSECT_ALL, SETOPCMD_EXCEPT, SETOPCMD_EXCEPT_ALL } SetOpCmd; typedef struct SetOp { Plan plan; SetOpCmd cmd; /* what to do */ int numCols; /* number of columns to check for * duplicate-ness */ AttrNumber *dupColIdx; /* their indexes in the target list */ Oid *dupOperators; /* equality operators to compare with */ AttrNumber flagColIdx; /* where is the flag column, if any */ } SetOp; /* ---------------- * limit node * * Note: as of Postgres 8.2, the offset and count expressions are expected * to yield int8, rather than int4 as before. * ---------------- */ typedef struct Limit { Plan plan; Node *limitOffset; /* OFFSET parameter, or NULL if none */ Node *limitCount; /* COUNT parameter, or NULL if none */ } Limit; #endif /* PLANNODES_H */