/*------------------------------------------------------------------------- * * nodeNestloop.c * routines to support nest-loop joins * * Portions Copyright (c) 1996-2003, PostgreSQL Global Development Group * Portions Copyright (c) 1994, Regents of the University of California * * * IDENTIFICATION * $PostgreSQL: pgsql/src/backend/executor/nodeNestloop.c,v 1.36 2003/11/29 19:51:48 pgsql Exp $ * *------------------------------------------------------------------------- */ /* * INTERFACE ROUTINES * ExecNestLoop - process a nestloop join of two plans * ExecInitNestLoop - initialize the join * ExecEndNestLoop - shut down the join */ #include "postgres.h" #include "executor/execdebug.h" #include "executor/nodeNestloop.h" #include "utils/memutils.h" /* ---------------------------------------------------------------- * ExecNestLoop(node) * * old comments * Returns the tuple joined from inner and outer tuples which * satisfies the qualification clause. * * It scans the inner relation to join with current outer tuple. * * If none is found, next tuple from the outer relation is retrieved * and the inner relation is scanned from the beginning again to join * with the outer tuple. * * NULL is returned if all the remaining outer tuples are tried and * all fail to join with the inner tuples. * * NULL is also returned if there is no tuple from inner relation. * * Conditions: * -- outerTuple contains current tuple from outer relation and * the right son(inner relation) maintains "cursor" at the tuple * returned previously. * This is achieved by maintaining a scan position on the outer * relation. * * Initial States: * -- the outer child and the inner child * are prepared to return the first tuple. * ---------------------------------------------------------------- */ TupleTableSlot * ExecNestLoop(NestLoopState *node) { PlanState *innerPlan; PlanState *outerPlan; TupleTableSlot *outerTupleSlot; TupleTableSlot *innerTupleSlot; List *joinqual; List *otherqual; ExprContext *econtext; /* * get information from the node */ ENL1_printf("getting info from node"); joinqual = node->js.joinqual; otherqual = node->js.ps.qual; outerPlan = outerPlanState(node); innerPlan = innerPlanState(node); econtext = node->js.ps.ps_ExprContext; /* * get the current outer tuple */ outerTupleSlot = node->js.ps.ps_OuterTupleSlot; econtext->ecxt_outertuple = outerTupleSlot; /* * Check to see if we're still projecting out tuples from a previous * join tuple (because there is a function-returning-set in the * projection expressions). If so, try to project another one. */ if (node->js.ps.ps_TupFromTlist) { TupleTableSlot *result; ExprDoneCond isDone; result = ExecProject(node->js.ps.ps_ProjInfo, &isDone); if (isDone == ExprMultipleResult) return result; /* Done with that source tuple... */ node->js.ps.ps_TupFromTlist = false; } /* * If we're doing an IN join, we want to return at most one row per * outer tuple; so we can stop scanning the inner scan if we matched * on the previous try. */ if (node->js.jointype == JOIN_IN && node->nl_MatchedOuter) node->nl_NeedNewOuter = true; /* * Reset per-tuple memory context to free any expression evaluation * storage allocated in the previous tuple cycle. Note this can't * happen until we're done projecting out tuples from a join tuple. */ ResetExprContext(econtext); /* * Ok, everything is setup for the join so now loop until we return a * qualifying join tuple. */ ENL1_printf("entering main loop"); for (;;) { /* * If we don't have an outer tuple, get the next one and reset the * inner scan. */ if (node->nl_NeedNewOuter) { ENL1_printf("getting new outer tuple"); outerTupleSlot = ExecProcNode(outerPlan); /* * if there are no more outer tuples, then the join is * complete.. */ if (TupIsNull(outerTupleSlot)) { ENL1_printf("no outer tuple, ending join"); return NULL; } ENL1_printf("saving new outer tuple information"); node->js.ps.ps_OuterTupleSlot = outerTupleSlot; econtext->ecxt_outertuple = outerTupleSlot; node->nl_NeedNewOuter = false; node->nl_MatchedOuter = false; /* * now rescan the inner plan */ ENL1_printf("rescanning inner plan"); /* * The scan key of the inner plan might depend on the current * outer tuple (e.g. in index scans), that's why we pass our * expr context. */ ExecReScan(innerPlan, econtext); } /* * we have an outerTuple, try to get the next inner tuple. */ ENL1_printf("getting new inner tuple"); innerTupleSlot = ExecProcNode(innerPlan); econtext->ecxt_innertuple = innerTupleSlot; if (TupIsNull(innerTupleSlot)) { ENL1_printf("no inner tuple, need new outer tuple"); node->nl_NeedNewOuter = true; if (!node->nl_MatchedOuter && node->js.jointype == JOIN_LEFT) { /* * We are doing an outer join and there were no join * matches for this outer tuple. Generate a fake join * tuple with nulls for the inner tuple, and return it if * it passes the non-join quals. */ econtext->ecxt_innertuple = node->nl_NullInnerTupleSlot; ENL1_printf("testing qualification for outer-join tuple"); if (ExecQual(otherqual, econtext, false)) { /* * qualification was satisfied so we project and * return the slot containing the result tuple using * ExecProject(). */ TupleTableSlot *result; ExprDoneCond isDone; ENL1_printf("qualification succeeded, projecting tuple"); result = ExecProject(node->js.ps.ps_ProjInfo, &isDone); if (isDone != ExprEndResult) { node->js.ps.ps_TupFromTlist = (isDone == ExprMultipleResult); return result; } } } /* * Otherwise just return to top of loop for a new outer tuple. */ continue; } /* * at this point we have a new pair of inner and outer tuples so * we test the inner and outer tuples to see if they satisfy the * node's qualification. * * Only the joinquals determine MatchedOuter status, but all quals * must pass to actually return the tuple. */ ENL1_printf("testing qualification"); if (ExecQual(joinqual, econtext, false)) { node->nl_MatchedOuter = true; if (otherqual == NIL || ExecQual(otherqual, econtext, false)) { /* * qualification was satisfied so we project and return * the slot containing the result tuple using * ExecProject(). */ TupleTableSlot *result; ExprDoneCond isDone; ENL1_printf("qualification succeeded, projecting tuple"); result = ExecProject(node->js.ps.ps_ProjInfo, &isDone); if (isDone != ExprEndResult) { node->js.ps.ps_TupFromTlist = (isDone == ExprMultipleResult); return result; } } /* If we didn't return a tuple, may need to set NeedNewOuter */ if (node->js.jointype == JOIN_IN) node->nl_NeedNewOuter = true; } /* * Tuple fails qual, so free per-tuple memory and try again. */ ResetExprContext(econtext); ENL1_printf("qualification failed, looping"); } } /* ---------------------------------------------------------------- * ExecInitNestLoop * ---------------------------------------------------------------- */ NestLoopState * ExecInitNestLoop(NestLoop *node, EState *estate) { NestLoopState *nlstate; NL1_printf("ExecInitNestLoop: %s\n", "initializing node"); /* * create state structure */ nlstate = makeNode(NestLoopState); nlstate->js.ps.plan = (Plan *) node; nlstate->js.ps.state = estate; /* * Miscellaneous initialization * * create expression context for node */ ExecAssignExprContext(estate, &nlstate->js.ps); /* * initialize child expressions */ nlstate->js.ps.targetlist = (List *) ExecInitExpr((Expr *) node->join.plan.targetlist, (PlanState *) nlstate); nlstate->js.ps.qual = (List *) ExecInitExpr((Expr *) node->join.plan.qual, (PlanState *) nlstate); nlstate->js.jointype = node->join.jointype; nlstate->js.joinqual = (List *) ExecInitExpr((Expr *) node->join.joinqual, (PlanState *) nlstate); /* * initialize child nodes */ outerPlanState(nlstate) = ExecInitNode(outerPlan(node), estate); innerPlanState(nlstate) = ExecInitNode(innerPlan(node), estate); #define NESTLOOP_NSLOTS 2 /* * tuple table initialization */ ExecInitResultTupleSlot(estate, &nlstate->js.ps); switch (node->join.jointype) { case JOIN_INNER: case JOIN_IN: break; case JOIN_LEFT: nlstate->nl_NullInnerTupleSlot = ExecInitNullTupleSlot(estate, ExecGetResultType(innerPlanState(nlstate))); break; default: elog(ERROR, "unrecognized join type: %d", (int) node->join.jointype); } /* * initialize tuple type and projection info */ ExecAssignResultTypeFromTL(&nlstate->js.ps); ExecAssignProjectionInfo(&nlstate->js.ps); /* * finally, wipe the current outer tuple clean. */ nlstate->js.ps.ps_OuterTupleSlot = NULL; nlstate->js.ps.ps_TupFromTlist = false; nlstate->nl_NeedNewOuter = true; nlstate->nl_MatchedOuter = false; NL1_printf("ExecInitNestLoop: %s\n", "node initialized"); return nlstate; } int ExecCountSlotsNestLoop(NestLoop *node) { return ExecCountSlotsNode(outerPlan(node)) + ExecCountSlotsNode(innerPlan(node)) + NESTLOOP_NSLOTS; } /* ---------------------------------------------------------------- * ExecEndNestLoop * * closes down scans and frees allocated storage * ---------------------------------------------------------------- */ void ExecEndNestLoop(NestLoopState *node) { NL1_printf("ExecEndNestLoop: %s\n", "ending node processing"); /* * Free the exprcontext */ ExecFreeExprContext(&node->js.ps); /* * clean out the tuple table */ ExecClearTuple(node->js.ps.ps_ResultTupleSlot); /* * close down subplans */ ExecEndNode(outerPlanState(node)); ExecEndNode(innerPlanState(node)); NL1_printf("ExecEndNestLoop: %s\n", "node processing ended"); } /* ---------------------------------------------------------------- * ExecReScanNestLoop * ---------------------------------------------------------------- */ void ExecReScanNestLoop(NestLoopState *node, ExprContext *exprCtxt) { PlanState *outerPlan = outerPlanState(node); /* * If outerPlan->chgParam is not null then plan will be automatically * re-scanned by first ExecProcNode. innerPlan is re-scanned for each * new outer tuple and MUST NOT be re-scanned from here or you'll get * troubles from inner index scans when outer Vars are used as * run-time keys... */ if (outerPlan->chgParam == NULL) ExecReScan(outerPlan, exprCtxt); /* let outerPlan to free its result tuple ... */ node->js.ps.ps_OuterTupleSlot = NULL; node->js.ps.ps_TupFromTlist = false; node->nl_NeedNewOuter = true; node->nl_MatchedOuter = false; }