nodeAgg.h File Reference

#include "nodes/execnodes.h"

Include dependency graph for nodeAgg.h:

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Go to the source code of this file.

Data Structures
struct	AggStatePerTransData
struct	AggStatePerAggData
struct	AggStatePerGroupData
struct	AggStatePerPhaseData
struct	AggStatePerHashData

Macros
#define	FIELDNO_AGGSTATEPERGROUPDATA_TRANSVALUE   0
#define	FIELDNO_AGGSTATEPERGROUPDATA_TRANSVALUEISNULL   1
#define	FIELDNO_AGGSTATEPERGROUPDATA_NOTRANSVALUE   2

Typedefs
typedef struct AggStatePerTransData	AggStatePerTransData
typedef struct AggStatePerAggData	AggStatePerAggData
typedef struct AggStatePerGroupData	AggStatePerGroupData
typedef struct AggStatePerPhaseData	AggStatePerPhaseData
typedef struct AggStatePerHashData	AggStatePerHashData

Functions
AggState *	ExecInitAgg (Agg *node, EState *estate, int eflags)
void	ExecEndAgg (AggState *node)
void	ExecReScanAgg (AggState *node)
Size	hash_agg_entry_size (int numTrans, Size tupleWidth, Size transitionSpace)
void	hash_agg_set_limits (double hashentrysize, uint64 input_groups, int used_bits, Size *mem_limit, uint64 *ngroups_limit, int *num_partitions)

Macro Definition Documentation

FIELDNO_AGGSTATEPERGROUPDATA_NOTRANSVALUE

#define FIELDNO_AGGSTATEPERGROUPDATA_NOTRANSVALUE   2

Definition at line 248 of file nodeAgg.h.

Referenced by llvm_compile_expr().

FIELDNO_AGGSTATEPERGROUPDATA_TRANSVALUE

#define FIELDNO_AGGSTATEPERGROUPDATA_TRANSVALUE   0

Definition at line 243 of file nodeAgg.h.

Referenced by llvm_compile_expr().

FIELDNO_AGGSTATEPERGROUPDATA_TRANSVALUEISNULL

#define FIELDNO_AGGSTATEPERGROUPDATA_TRANSVALUEISNULL   1

Definition at line 245 of file nodeAgg.h.

Referenced by llvm_compile_expr().

Typedef Documentation

AggStatePerAggData

typedef struct AggStatePerAggData AggStatePerAggData

AggStatePerGroupData

typedef struct AggStatePerGroupData AggStatePerGroupData

AggStatePerHashData

typedef struct AggStatePerHashData AggStatePerHashData

AggStatePerPhaseData

typedef struct AggStatePerPhaseData AggStatePerPhaseData

AggStatePerTransData

typedef struct AggStatePerTransData AggStatePerTransData

Function Documentation

ExecEndAgg()

void ExecEndAgg

(

AggState *

node

)

Definition at line 4483 of file nodeAgg.c.

References AggState::aggcontexts, ExecClearTuple(), ExecEndNode(), ExecFreeExprContext(), AggState::hash_metacxt, hashagg_reset_spill_state(), AggState::hashcontext, Max, AggState::maxsets, MemoryContextDelete(), AggState::numtrans, outerPlan, outerPlanState, AggState::pertrans, ScanState::ps, ReScanExprContext(), AggState::sort_in, AggState::sort_out, AggStatePerTransData::sortstates, AggState::ss, ScanState::ss_ScanTupleSlot, and tuplesort_end().

Referenced by ExecEndNode().

{
    PlanState  *outerPlan;
    int         transno;
    int         numGroupingSets = Max(node->maxsets, 1);
    int         setno;

    /* Make sure we have closed any open tuplesorts */

    if (node->sort_in)
        tuplesort_end(node->sort_in);
    if (node->sort_out)
        tuplesort_end(node->sort_out);

    hashagg_reset_spill_state(node);

    if (node->hash_metacxt != NULL)
    {
        MemoryContextDelete(node->hash_metacxt);
        node->hash_metacxt = NULL;
    }

    for (transno = 0; transno < node->numtrans; transno++)
    {
        AggStatePerTrans pertrans = &node->pertrans[transno];

        for (setno = 0; setno < numGroupingSets; setno++)
        {
            if (pertrans->sortstates[setno])
                tuplesort_end(pertrans->sortstates[setno]);
        }
    }

    /* And ensure any agg shutdown callbacks have been called */
    for (setno = 0; setno < numGroupingSets; setno++)
        ReScanExprContext(node->aggcontexts[setno]);
    if (node->hashcontext)
        ReScanExprContext(node->hashcontext);

    /*
     * We don't actually free any ExprContexts here (see comment in
     * ExecFreeExprContext), just unlinking the output one from the plan node
     * suffices.
     */
    ExecFreeExprContext(&node->ss.ps);

    /* clean up tuple table */
    ExecClearTuple(node->ss.ss_ScanTupleSlot);

    outerPlan = outerPlanState(node);
    ExecEndNode(outerPlan);
}

ExecInitAgg()

AggState* ExecInitAgg	(	Agg *	node,
		EState *	estate,
		int	eflags
	)

Definition at line 3165 of file nodeAgg.c.

References ACL_EXECUTE, aclcheck_error(), ACLCHECK_OK, AggState::agg_done, AGG_HASHED, AGG_MIXED, AGG_PLAIN, AGG_SORTED, AggState::aggcontexts, AggStatePerAggData::aggdirectargs, Aggref::aggdirectargs, AGGFNOID, Aggref::aggfnoid, Aggref::agglevelsup, AggrefExprState::aggno, AggStatePerPhaseData::aggnode, AggStatePerHashData::aggnode, AggStatePerAggData::aggref, AggrefExprState::aggref, AggState::aggs, AggStatePerTransData::aggshared, Aggref::aggsplit, Agg::aggsplit, AggState::aggsplit, AggStatePerPhaseData::aggstrategy, Agg::aggstrategy, AggState::aggstrategy, Aggref::aggtranstype, Aggref::aggtype, ALLOCSET_DEFAULT_SIZES, AllocSetContextCreate, Assert, bms_add_member(), bms_add_members(), bms_next_member(), build_aggregate_finalfn_expr(), build_hash_tables(), build_pertrans_for_aggref(), castNode, Agg::chain, CreateWorkExprContext(), AggState::curperagg, AggState::curpertrans, AggState::current_set, DO_AGGSPLIT_COMBINE, DO_AGGSPLIT_DESERIALIZE, DO_AGGSPLIT_SERIALIZE, DO_AGGSPLIT_SKIPFINAL, ExprContext::ecxt_aggnulls, ExprContext::ecxt_aggvalues, elog, AggStatePerPhaseData::eqfunctions, ereport, errcode(), errmsg(), ERROR, EState::es_query_cxt, AggStatePerPhaseData::evaltrans, AggStatePerPhaseData::evaltrans_cache, EXEC_FLAG_BACKWARD, EXEC_FLAG_MARK, EXEC_FLAG_REWIND, ExecAgg(), ExecAssignExprContext(), ExecAssignProjectionInfo(), ExecBuildAggTrans(), ExecCreateScanSlotFromOuterPlan(), ExecGetResultSlotOps(), ExecInitExprList(), ExecInitExtraTupleSlot(), ExecInitNode(), ExecInitQual(), ExecInitResultTupleSlotTL(), PlanState::ExecProcNode, execTuplesMatchPrepare(), AggStatePerAggData::finalfn, AggStatePerAggData::finalfn_oid, find_compatible_peragg(), find_compatible_pertrans(), find_hash_columns(), fmgr_info(), fmgr_info_set_expr, FUNC_MAX_ARGS, get_aggregate_argtypes(), get_func_name(), get_typlenbyval(), GetAggInitVal(), GETSTRUCT, GetUserId(), AggStatePerPhaseData::grouped_cols, Agg::groupingSets, AggState::grp_firstTuple, Agg::grpColIdx, Agg::grpCollations, Agg::grpOperators, AggStatePerPhaseData::gset_lengths, hash_agg_entry_size(), hash_agg_set_limits(), AggState::hashcontext, HeapTupleIsValid, i, initialize_phase(), initValue(), AggState::input_done, Aggref::inputcollid, InvalidOid, InvokeFunctionExecuteHook, lcons_int(), Plan::lefttree, lfirst, list_length(), list_nth_node, makeNode, Max, AggState::maxsets, NIL, AggState::numaggs, AggStatePerHashData::numCols, Agg::numCols, AggStatePerAggData::numFinalArgs, AggState::numphases, AggStatePerPhaseData::numsets, AggState::numtrans, OBJECT_AGGREGATE, OBJECT_FUNCTION, ObjectIdGetDatum, OidIsValid, PlanState::outerops, PlanState::outeropsfixed, PlanState::outeropsset, outerPlan, outerPlanState, palloc(), palloc0(), AggState::peragg, AggState::pergroups, AggState::pertrans, pg_proc_aclcheck(), Agg::plan, PlanState::plan, Plan::plan_width, PROCOID, AggState::projected_set, ScanState::ps, PlanState::ps_ExprContext, Plan::qual, PlanState::qual, ReleaseSysCache(), AggStatePerAggData::resulttypeByVal, AggStatePerAggData::resulttypeLen, SearchSysCache1(), select_current_set(), AggStatePerAggData::shareable, AggState::sort_in, AggState::sort_out, AggState::sort_slot, AggStatePerPhaseData::sortnode, AggState::ss, ScanState::ss_ScanTupleSlot, PlanState::state, SysCacheGetAttr(), AggState::tmpcontext, Agg::transitionSpace, AggStatePerAggData::transno, TupleTableSlot::tts_tupleDescriptor, TTSOpsMinimalTuple, and TTSOpsVirtual.

Referenced by ExecInitNode().

{
    AggState   *aggstate;
    AggStatePerAgg peraggs;
    AggStatePerTrans pertransstates;
    AggStatePerGroup *pergroups;
    Plan       *outerPlan;
    ExprContext *econtext;
    TupleDesc   scanDesc;
    int         numaggs,
                transno,
                aggno;
    int         phase;
    int         phaseidx;
    ListCell   *l;
    Bitmapset  *all_grouped_cols = NULL;
    int         numGroupingSets = 1;
    int         numPhases;
    int         numHashes;
    int         i = 0;
    int         j = 0;
    bool        use_hashing = (node->aggstrategy == AGG_HASHED ||
                               node->aggstrategy == AGG_MIXED);

    /* check for unsupported flags */
    Assert(!(eflags & (EXEC_FLAG_BACKWARD | EXEC_FLAG_MARK)));

    /*
     * create state structure
     */
    aggstate = makeNode(AggState);
    aggstate->ss.ps.plan = (Plan *) node;
    aggstate->ss.ps.state = estate;
    aggstate->ss.ps.ExecProcNode = ExecAgg;

    aggstate->aggs = NIL;
    aggstate->numaggs = 0;
    aggstate->numtrans = 0;
    aggstate->aggstrategy = node->aggstrategy;
    aggstate->aggsplit = node->aggsplit;
    aggstate->maxsets = 0;
    aggstate->projected_set = -1;
    aggstate->current_set = 0;
    aggstate->peragg = NULL;
    aggstate->pertrans = NULL;
    aggstate->curperagg = NULL;
    aggstate->curpertrans = NULL;
    aggstate->input_done = false;
    aggstate->agg_done = false;
    aggstate->pergroups = NULL;
    aggstate->grp_firstTuple = NULL;
    aggstate->sort_in = NULL;
    aggstate->sort_out = NULL;

    /*
     * phases[0] always exists, but is dummy in sorted/plain mode
     */
    numPhases = (use_hashing ? 1 : 2);
    numHashes = (use_hashing ? 1 : 0);

    /*
     * Calculate the maximum number of grouping sets in any phase; this
     * determines the size of some allocations.  Also calculate the number of
     * phases, since all hashed/mixed nodes contribute to only a single phase.
     */
    if (node->groupingSets)
    {
        numGroupingSets = list_length(node->groupingSets);

        foreach(l, node->chain)
        {
            Agg        *agg = lfirst(l);

            numGroupingSets = Max(numGroupingSets,
                                  list_length(agg->groupingSets));

            /*
             * additional AGG_HASHED aggs become part of phase 0, but all
             * others add an extra phase.
             */
            if (agg->aggstrategy != AGG_HASHED)
                ++numPhases;
            else
                ++numHashes;
        }
    }

    aggstate->maxsets = numGroupingSets;
    aggstate->numphases = numPhases;

    aggstate->aggcontexts = (ExprContext **)
        palloc0(sizeof(ExprContext *) * numGroupingSets);

    /*
     * Create expression contexts.  We need three or more, one for
     * per-input-tuple processing, one for per-output-tuple processing, one
     * for all the hashtables, and one for each grouping set.  The per-tuple
     * memory context of the per-grouping-set ExprContexts (aggcontexts)
     * replaces the standalone memory context formerly used to hold transition
     * values.  We cheat a little by using ExecAssignExprContext() to build
     * all of them.
     *
     * NOTE: the details of what is stored in aggcontexts and what is stored
     * in the regular per-query memory context are driven by a simple
     * decision: we want to reset the aggcontext at group boundaries (if not
     * hashing) and in ExecReScanAgg to recover no-longer-wanted space.
     */
    ExecAssignExprContext(estate, &aggstate->ss.ps);
    aggstate->tmpcontext = aggstate->ss.ps.ps_ExprContext;

    for (i = 0; i < numGroupingSets; ++i)
    {
        ExecAssignExprContext(estate, &aggstate->ss.ps);
        aggstate->aggcontexts[i] = aggstate->ss.ps.ps_ExprContext;
    }

    if (use_hashing)
        aggstate->hashcontext = CreateWorkExprContext(estate);

    ExecAssignExprContext(estate, &aggstate->ss.ps);

    /*
     * Initialize child nodes.
     *
     * If we are doing a hashed aggregation then the child plan does not need
     * to handle REWIND efficiently; see ExecReScanAgg.
     */
    if (node->aggstrategy == AGG_HASHED)
        eflags &= ~EXEC_FLAG_REWIND;
    outerPlan = outerPlan(node);
    outerPlanState(aggstate) = ExecInitNode(outerPlan, estate, eflags);

    /*
     * initialize source tuple type.
     */
    aggstate->ss.ps.outerops =
        ExecGetResultSlotOps(outerPlanState(&aggstate->ss),
                             &aggstate->ss.ps.outeropsfixed);
    aggstate->ss.ps.outeropsset = true;

    ExecCreateScanSlotFromOuterPlan(estate, &aggstate->ss,
                                    aggstate->ss.ps.outerops);
    scanDesc = aggstate->ss.ss_ScanTupleSlot->tts_tupleDescriptor;

    /*
     * If there are more than two phases (including a potential dummy phase
     * 0), input will be resorted using tuplesort. Need a slot for that.
     */
    if (numPhases > 2)
    {
        aggstate->sort_slot = ExecInitExtraTupleSlot(estate, scanDesc,
                                                     &TTSOpsMinimalTuple);

        /*
         * The output of the tuplesort, and the output from the outer child
         * might not use the same type of slot. In most cases the child will
         * be a Sort, and thus return a TTSOpsMinimalTuple type slot - but the
         * input can also be presorted due an index, in which case it could be
         * a different type of slot.
         *
         * XXX: For efficiency it would be good to instead/additionally
         * generate expressions with corresponding settings of outerops* for
         * the individual phases - deforming is often a bottleneck for
         * aggregations with lots of rows per group. If there's multiple
         * sorts, we know that all but the first use TTSOpsMinimalTuple (via
         * the nodeAgg.c internal tuplesort).
         */
        if (aggstate->ss.ps.outeropsfixed &&
            aggstate->ss.ps.outerops != &TTSOpsMinimalTuple)
            aggstate->ss.ps.outeropsfixed = false;
    }

    /*
     * Initialize result type, slot and projection.
     */
    ExecInitResultTupleSlotTL(&aggstate->ss.ps, &TTSOpsVirtual);
    ExecAssignProjectionInfo(&aggstate->ss.ps, NULL);

    /*
     * initialize child expressions
     *
     * We expect the parser to have checked that no aggs contain other agg
     * calls in their arguments (and just to be sure, we verify it again while
     * initializing the plan node).  This would make no sense under SQL
     * semantics, and it's forbidden by the spec.  Because it is true, we
     * don't need to worry about evaluating the aggs in any particular order.
     *
     * Note: execExpr.c finds Aggrefs for us, and adds their AggrefExprState
     * nodes to aggstate->aggs.  Aggrefs in the qual are found here; Aggrefs
     * in the targetlist are found during ExecAssignProjectionInfo, below.
     */
    aggstate->ss.ps.qual =
        ExecInitQual(node->plan.qual, (PlanState *) aggstate);

    /*
     * We should now have found all Aggrefs in the targetlist and quals.
     */
    numaggs = aggstate->numaggs;
    Assert(numaggs == list_length(aggstate->aggs));

    /*
     * For each phase, prepare grouping set data and fmgr lookup data for
     * compare functions.  Accumulate all_grouped_cols in passing.
     */
    aggstate->phases = palloc0(numPhases * sizeof(AggStatePerPhaseData));

    aggstate->num_hashes = numHashes;
    if (numHashes)
    {
        aggstate->perhash = palloc0(sizeof(AggStatePerHashData) * numHashes);
        aggstate->phases[0].numsets = 0;
        aggstate->phases[0].gset_lengths = palloc(numHashes * sizeof(int));
        aggstate->phases[0].grouped_cols = palloc(numHashes * sizeof(Bitmapset *));
    }

    phase = 0;
    for (phaseidx = 0; phaseidx <= list_length(node->chain); ++phaseidx)
    {
        Agg        *aggnode;
        Sort       *sortnode;

        if (phaseidx > 0)
        {
            aggnode = list_nth_node(Agg, node->chain, phaseidx - 1);
            sortnode = castNode(Sort, aggnode->plan.lefttree);
        }
        else
        {
            aggnode = node;
            sortnode = NULL;
        }

        Assert(phase <= 1 || sortnode);

        if (aggnode->aggstrategy == AGG_HASHED
            || aggnode->aggstrategy == AGG_MIXED)
        {
            AggStatePerPhase phasedata = &aggstate->phases[0];
            AggStatePerHash perhash;
            Bitmapset  *cols = NULL;

            Assert(phase == 0);
            i = phasedata->numsets++;
            perhash = &aggstate->perhash[i];

            /* phase 0 always points to the "real" Agg in the hash case */
            phasedata->aggnode = node;
            phasedata->aggstrategy = node->aggstrategy;

            /* but the actual Agg node representing this hash is saved here */
            perhash->aggnode = aggnode;

            phasedata->gset_lengths[i] = perhash->numCols = aggnode->numCols;

            for (j = 0; j < aggnode->numCols; ++j)
                cols = bms_add_member(cols, aggnode->grpColIdx[j]);

            phasedata->grouped_cols[i] = cols;

            all_grouped_cols = bms_add_members(all_grouped_cols, cols);
            continue;
        }
        else
        {
            AggStatePerPhase phasedata = &aggstate->phases[++phase];
            int         num_sets;

            phasedata->numsets = num_sets = list_length(aggnode->groupingSets);

            if (num_sets)
            {
                phasedata->gset_lengths = palloc(num_sets * sizeof(int));
                phasedata->grouped_cols = palloc(num_sets * sizeof(Bitmapset *));

                i = 0;
                foreach(l, aggnode->groupingSets)
                {
                    int         current_length = list_length(lfirst(l));
                    Bitmapset  *cols = NULL;

                    /* planner forces this to be correct */
                    for (j = 0; j < current_length; ++j)
                        cols = bms_add_member(cols, aggnode->grpColIdx[j]);

                    phasedata->grouped_cols[i] = cols;
                    phasedata->gset_lengths[i] = current_length;

                    ++i;
                }

                all_grouped_cols = bms_add_members(all_grouped_cols,
                                                   phasedata->grouped_cols[0]);
            }
            else
            {
                Assert(phaseidx == 0);

                phasedata->gset_lengths = NULL;
                phasedata->grouped_cols = NULL;
            }

            /*
             * If we are grouping, precompute fmgr lookup data for inner loop.
             */
            if (aggnode->aggstrategy == AGG_SORTED)
            {
                int         i = 0;

                Assert(aggnode->numCols > 0);

                /*
                 * Build a separate function for each subset of columns that
                 * need to be compared.
                 */
                phasedata->eqfunctions =
                    (ExprState **) palloc0(aggnode->numCols * sizeof(ExprState *));

                /* for each grouping set */
                for (i = 0; i < phasedata->numsets; i++)
                {
                    int         length = phasedata->gset_lengths[i];

                    if (phasedata->eqfunctions[length - 1] != NULL)
                        continue;

                    phasedata->eqfunctions[length - 1] =
                        execTuplesMatchPrepare(scanDesc,
                                               length,
                                               aggnode->grpColIdx,
                                               aggnode->grpOperators,
                                               aggnode->grpCollations,
                                               (PlanState *) aggstate);
                }

                /* and for all grouped columns, unless already computed */
                if (phasedata->eqfunctions[aggnode->numCols - 1] == NULL)
                {
                    phasedata->eqfunctions[aggnode->numCols - 1] =
                        execTuplesMatchPrepare(scanDesc,
                                               aggnode->numCols,
                                               aggnode->grpColIdx,
                                               aggnode->grpOperators,
                                               aggnode->grpCollations,
                                               (PlanState *) aggstate);
                }
            }

            phasedata->aggnode = aggnode;
            phasedata->aggstrategy = aggnode->aggstrategy;
            phasedata->sortnode = sortnode;
        }
    }

    /*
     * Convert all_grouped_cols to a descending-order list.
     */
    i = -1;
    while ((i = bms_next_member(all_grouped_cols, i)) >= 0)
        aggstate->all_grouped_cols = lcons_int(i, aggstate->all_grouped_cols);

    /*
     * Set up aggregate-result storage in the output expr context, and also
     * allocate my private per-agg working storage
     */
    econtext = aggstate->ss.ps.ps_ExprContext;
    econtext->ecxt_aggvalues = (Datum *) palloc0(sizeof(Datum) * numaggs);
    econtext->ecxt_aggnulls = (bool *) palloc0(sizeof(bool) * numaggs);

    peraggs = (AggStatePerAgg) palloc0(sizeof(AggStatePerAggData) * numaggs);
    pertransstates = (AggStatePerTrans) palloc0(sizeof(AggStatePerTransData) * numaggs);

    aggstate->peragg = peraggs;
    aggstate->pertrans = pertransstates;


    aggstate->all_pergroups =
        (AggStatePerGroup *) palloc0(sizeof(AggStatePerGroup)
                                     * (numGroupingSets + numHashes));
    pergroups = aggstate->all_pergroups;

    if (node->aggstrategy != AGG_HASHED)
    {
        for (i = 0; i < numGroupingSets; i++)
        {
            pergroups[i] = (AggStatePerGroup) palloc0(sizeof(AggStatePerGroupData)
                                                      * numaggs);
        }

        aggstate->pergroups = pergroups;
        pergroups += numGroupingSets;
    }

    /*
     * Hashing can only appear in the initial phase.
     */
    if (use_hashing)
    {
        Plan       *outerplan = outerPlan(node);
        uint64      totalGroups = 0;
        int         i;

        aggstate->hash_metacxt = AllocSetContextCreate(aggstate->ss.ps.state->es_query_cxt,
                                                       "HashAgg meta context",
                                                       ALLOCSET_DEFAULT_SIZES);
        aggstate->hash_spill_slot = ExecInitExtraTupleSlot(estate, scanDesc,
                                                           &TTSOpsMinimalTuple);

        /* this is an array of pointers, not structures */
        aggstate->hash_pergroup = pergroups;

        aggstate->hashentrysize = hash_agg_entry_size(aggstate->numtrans,
                                                      outerplan->plan_width,
                                                      node->transitionSpace);

        /*
         * Consider all of the grouping sets together when setting the limits
         * and estimating the number of partitions. This can be inaccurate
         * when there is more than one grouping set, but should still be
         * reasonable.
         */
        for (i = 0; i < aggstate->num_hashes; i++)
            totalGroups += aggstate->perhash[i].aggnode->numGroups;

        hash_agg_set_limits(aggstate->hashentrysize, totalGroups, 0,
                            &aggstate->hash_mem_limit,
                            &aggstate->hash_ngroups_limit,
                            &aggstate->hash_planned_partitions);
        find_hash_columns(aggstate);
        build_hash_tables(aggstate);
        aggstate->table_filled = false;
    }

    /*
     * Initialize current phase-dependent values to initial phase. The initial
     * phase is 1 (first sort pass) for all strategies that use sorting (if
     * hashing is being done too, then phase 0 is processed last); but if only
     * hashing is being done, then phase 0 is all there is.
     */
    if (node->aggstrategy == AGG_HASHED)
    {
        aggstate->current_phase = 0;
        initialize_phase(aggstate, 0);
        select_current_set(aggstate, 0, true);
    }
    else
    {
        aggstate->current_phase = 1;
        initialize_phase(aggstate, 1);
        select_current_set(aggstate, 0, false);
    }

    /* -----------------
     * Perform lookups of aggregate function info, and initialize the
     * unchanging fields of the per-agg and per-trans data.
     *
     * We try to optimize by detecting duplicate aggregate functions so that
     * their state and final values are re-used, rather than needlessly being
     * re-calculated independently. We also detect aggregates that are not
     * the same, but which can share the same transition state.
     *
     * Scenarios:
     *
     * 1. Identical aggregate function calls appear in the query:
     *
     *    SELECT SUM(x) FROM ... HAVING SUM(x) > 0
     *
     *    Since these aggregates are identical, we only need to calculate
     *    the value once. Both aggregates will share the same 'aggno' value.
     *
     * 2. Two different aggregate functions appear in the query, but the
     *    aggregates have the same arguments, transition functions and
     *    initial values (and, presumably, different final functions):
     *
     *    SELECT AVG(x), STDDEV(x) FROM ...
     *
     *    In this case we must create a new peragg for the varying aggregate,
     *    and we need to call the final functions separately, but we need
     *    only run the transition function once.  (This requires that the
     *    final functions be nondestructive of the transition state, but
     *    that's required anyway for other reasons.)
     *
     * For either of these optimizations to be valid, all aggregate properties
     * used in the transition phase must be the same, including any modifiers
     * such as ORDER BY, DISTINCT and FILTER, and the arguments mustn't
     * contain any volatile functions.
     * -----------------
     */
    aggno = -1;
    transno = -1;
    foreach(l, aggstate->aggs)
    {
        AggrefExprState *aggrefstate = (AggrefExprState *) lfirst(l);
        Aggref     *aggref = aggrefstate->aggref;
        AggStatePerAgg peragg;
        AggStatePerTrans pertrans;
        int         existing_aggno;
        int         existing_transno;
        List       *same_input_transnos;
        Oid         inputTypes[FUNC_MAX_ARGS];
        int         numArguments;
        int         numDirectArgs;
        HeapTuple   aggTuple;
        Form_pg_aggregate aggform;
        AclResult   aclresult;
        Oid         transfn_oid,
                    finalfn_oid;
        bool        shareable;
        Oid         serialfn_oid,
                    deserialfn_oid;
        Expr       *finalfnexpr;
        Oid         aggtranstype;
        Datum       textInitVal;
        Datum       initValue;
        bool        initValueIsNull;

        /* Planner should have assigned aggregate to correct level */
        Assert(aggref->agglevelsup == 0);
        /* ... and the split mode should match */
        Assert(aggref->aggsplit == aggstate->aggsplit);

        /* 1. Check for already processed aggs which can be re-used */
        existing_aggno = find_compatible_peragg(aggref, aggstate, aggno,
                                                &same_input_transnos);
        if (existing_aggno != -1)
        {
            /*
             * Existing compatible agg found. so just point the Aggref to the
             * same per-agg struct.
             */
            aggrefstate->aggno = existing_aggno;
            continue;
        }

        /* Mark Aggref state node with assigned index in the result array */
        peragg = &peraggs[++aggno];
        peragg->aggref = aggref;
        aggrefstate->aggno = aggno;

        /* Fetch the pg_aggregate row */
        aggTuple = SearchSysCache1(AGGFNOID,
                                   ObjectIdGetDatum(aggref->aggfnoid));
        if (!HeapTupleIsValid(aggTuple))
            elog(ERROR, "cache lookup failed for aggregate %u",
                 aggref->aggfnoid);
        aggform = (Form_pg_aggregate) GETSTRUCT(aggTuple);

        /* Check permission to call aggregate function */
        aclresult = pg_proc_aclcheck(aggref->aggfnoid, GetUserId(),
                                     ACL_EXECUTE);
        if (aclresult != ACLCHECK_OK)
            aclcheck_error(aclresult, OBJECT_AGGREGATE,
                           get_func_name(aggref->aggfnoid));
        InvokeFunctionExecuteHook(aggref->aggfnoid);

        /* planner recorded transition state type in the Aggref itself */
        aggtranstype = aggref->aggtranstype;
        Assert(OidIsValid(aggtranstype));

        /*
         * If this aggregation is performing state combines, then instead of
         * using the transition function, we'll use the combine function
         */
        if (DO_AGGSPLIT_COMBINE(aggstate->aggsplit))
        {
            transfn_oid = aggform->aggcombinefn;

            /* If not set then the planner messed up */
            if (!OidIsValid(transfn_oid))
                elog(ERROR, "combinefn not set for aggregate function");
        }
        else
            transfn_oid = aggform->aggtransfn;

        /* Final function only required if we're finalizing the aggregates */
        if (DO_AGGSPLIT_SKIPFINAL(aggstate->aggsplit))
            peragg->finalfn_oid = finalfn_oid = InvalidOid;
        else
            peragg->finalfn_oid = finalfn_oid = aggform->aggfinalfn;

        /*
         * If finalfn is marked read-write, we can't share transition states;
         * but it is okay to share states for AGGMODIFY_SHAREABLE aggs.  Also,
         * if we're not executing the finalfn here, we can share regardless.
         */
        shareable = (aggform->aggfinalmodify != AGGMODIFY_READ_WRITE) ||
            (finalfn_oid == InvalidOid);
        peragg->shareable = shareable;

        serialfn_oid = InvalidOid;
        deserialfn_oid = InvalidOid;

        /*
         * Check if serialization/deserialization is required.  We only do it
         * for aggregates that have transtype INTERNAL.
         */
        if (aggtranstype == INTERNALOID)
        {
            /*
             * The planner should only have generated a serialize agg node if
             * every aggregate with an INTERNAL state has a serialization
             * function.  Verify that.
             */
            if (DO_AGGSPLIT_SERIALIZE(aggstate->aggsplit))
            {
                /* serialization only valid when not running finalfn */
                Assert(DO_AGGSPLIT_SKIPFINAL(aggstate->aggsplit));

                if (!OidIsValid(aggform->aggserialfn))
                    elog(ERROR, "serialfunc not provided for serialization aggregation");
                serialfn_oid = aggform->aggserialfn;
            }

            /* Likewise for deserialization functions */
            if (DO_AGGSPLIT_DESERIALIZE(aggstate->aggsplit))
            {
                /* deserialization only valid when combining states */
                Assert(DO_AGGSPLIT_COMBINE(aggstate->aggsplit));

                if (!OidIsValid(aggform->aggdeserialfn))
                    elog(ERROR, "deserialfunc not provided for deserialization aggregation");
                deserialfn_oid = aggform->aggdeserialfn;
            }
        }

        /* Check that aggregate owner has permission to call component fns */
        {
            HeapTuple   procTuple;
            Oid         aggOwner;

            procTuple = SearchSysCache1(PROCOID,
                                        ObjectIdGetDatum(aggref->aggfnoid));
            if (!HeapTupleIsValid(procTuple))
                elog(ERROR, "cache lookup failed for function %u",
                     aggref->aggfnoid);
            aggOwner = ((Form_pg_proc) GETSTRUCT(procTuple))->proowner;
            ReleaseSysCache(procTuple);

            aclresult = pg_proc_aclcheck(transfn_oid, aggOwner,
                                         ACL_EXECUTE);
            if (aclresult != ACLCHECK_OK)
                aclcheck_error(aclresult, OBJECT_FUNCTION,
                               get_func_name(transfn_oid));
            InvokeFunctionExecuteHook(transfn_oid);
            if (OidIsValid(finalfn_oid))
            {
                aclresult = pg_proc_aclcheck(finalfn_oid, aggOwner,
                                             ACL_EXECUTE);
                if (aclresult != ACLCHECK_OK)
                    aclcheck_error(aclresult, OBJECT_FUNCTION,
                                   get_func_name(finalfn_oid));
                InvokeFunctionExecuteHook(finalfn_oid);
            }
            if (OidIsValid(serialfn_oid))
            {
                aclresult = pg_proc_aclcheck(serialfn_oid, aggOwner,
                                             ACL_EXECUTE);
                if (aclresult != ACLCHECK_OK)
                    aclcheck_error(aclresult, OBJECT_FUNCTION,
                                   get_func_name(serialfn_oid));
                InvokeFunctionExecuteHook(serialfn_oid);
            }
            if (OidIsValid(deserialfn_oid))
            {
                aclresult = pg_proc_aclcheck(deserialfn_oid, aggOwner,
                                             ACL_EXECUTE);
                if (aclresult != ACLCHECK_OK)
                    aclcheck_error(aclresult, OBJECT_FUNCTION,
                                   get_func_name(deserialfn_oid));
                InvokeFunctionExecuteHook(deserialfn_oid);
            }
        }

        /*
         * Get actual datatypes of the (nominal) aggregate inputs.  These
         * could be different from the agg's declared input types, when the
         * agg accepts ANY or a polymorphic type.
         */
        numArguments = get_aggregate_argtypes(aggref, inputTypes);

        /* Count the "direct" arguments, if any */
        numDirectArgs = list_length(aggref->aggdirectargs);

        /* Detect how many arguments to pass to the finalfn */
        if (aggform->aggfinalextra)
            peragg->numFinalArgs = numArguments + 1;
        else
            peragg->numFinalArgs = numDirectArgs + 1;

        /* Initialize any direct-argument expressions */
        peragg->aggdirectargs = ExecInitExprList(aggref->aggdirectargs,
                                                 (PlanState *) aggstate);

        /*
         * build expression trees using actual argument & result types for the
         * finalfn, if it exists and is required.
         */
        if (OidIsValid(finalfn_oid))
        {
            build_aggregate_finalfn_expr(inputTypes,
                                         peragg->numFinalArgs,
                                         aggtranstype,
                                         aggref->aggtype,
                                         aggref->inputcollid,
                                         finalfn_oid,
                                         &finalfnexpr);
            fmgr_info(finalfn_oid, &peragg->finalfn);
            fmgr_info_set_expr((Node *) finalfnexpr, &peragg->finalfn);
        }

        /* get info about the output value's datatype */
        get_typlenbyval(aggref->aggtype,
                        &peragg->resulttypeLen,
                        &peragg->resulttypeByVal);

        /*
         * initval is potentially null, so don't try to access it as a struct
         * field. Must do it the hard way with SysCacheGetAttr.
         */
        textInitVal = SysCacheGetAttr(AGGFNOID, aggTuple,
                                      Anum_pg_aggregate_agginitval,
                                      &initValueIsNull);
        if (initValueIsNull)
            initValue = (Datum) 0;
        else
            initValue = GetAggInitVal(textInitVal, aggtranstype);

        /*
         * 2. Build working state for invoking the transition function, or
         * look up previously initialized working state, if we can share it.
         *
         * find_compatible_peragg() already collected a list of shareable
         * per-Trans's with the same inputs. Check if any of them have the
         * same transition function and initial value.
         */
        existing_transno = find_compatible_pertrans(aggstate, aggref,
                                                    shareable,
                                                    transfn_oid, aggtranstype,
                                                    serialfn_oid, deserialfn_oid,
                                                    initValue, initValueIsNull,
                                                    same_input_transnos);
        if (existing_transno != -1)
        {
            /*
             * Existing compatible trans found, so just point the 'peragg' to
             * the same per-trans struct, and mark the trans state as shared.
             */
            pertrans = &pertransstates[existing_transno];
            pertrans->aggshared = true;
            peragg->transno = existing_transno;
        }
        else
        {
            pertrans = &pertransstates[++transno];
            build_pertrans_for_aggref(pertrans, aggstate, estate,
                                      aggref, transfn_oid, aggtranstype,
                                      serialfn_oid, deserialfn_oid,
                                      initValue, initValueIsNull,
                                      inputTypes, numArguments);
            peragg->transno = transno;
        }
        ReleaseSysCache(aggTuple);
    }

    /*
     * Update aggstate->numaggs to be the number of unique aggregates found.
     * Also set numstates to the number of unique transition states found.
     */
    aggstate->numaggs = aggno + 1;
    aggstate->numtrans = transno + 1;

    /*
     * Last, check whether any more aggregates got added onto the node while
     * we processed the expressions for the aggregate arguments (including not
     * only the regular arguments and FILTER expressions handled immediately
     * above, but any direct arguments we might've handled earlier).  If so,
     * we have nested aggregate functions, which is semantically nonsensical,
     * so complain.  (This should have been caught by the parser, so we don't
     * need to work hard on a helpful error message; but we defend against it
     * here anyway, just to be sure.)
     */
    if (numaggs != list_length(aggstate->aggs))
        ereport(ERROR,
                (errcode(ERRCODE_GROUPING_ERROR),
                 errmsg("aggregate function calls cannot be nested")));

    /*
     * Build expressions doing all the transition work at once. We build a
     * different one for each phase, as the number of transition function
     * invocation can differ between phases. Note this'll work both for
     * transition and combination functions (although there'll only be one
     * phase in the latter case).
     */
    for (phaseidx = 0; phaseidx < aggstate->numphases; phaseidx++)
    {
        AggStatePerPhase phase = &aggstate->phases[phaseidx];
        bool        dohash = false;
        bool        dosort = false;

        /* phase 0 doesn't necessarily exist */
        if (!phase->aggnode)
            continue;

        if (aggstate->aggstrategy == AGG_MIXED && phaseidx == 1)
        {
            /*
             * Phase one, and only phase one, in a mixed agg performs both
             * sorting and aggregation.
             */
            dohash = true;
            dosort = true;
        }
        else if (aggstate->aggstrategy == AGG_MIXED && phaseidx == 0)
        {
            /*
             * No need to compute a transition function for an AGG_MIXED phase
             * 0 - the contents of the hashtables will have been computed
             * during phase 1.
             */
            continue;
        }
        else if (phase->aggstrategy == AGG_PLAIN ||
                 phase->aggstrategy == AGG_SORTED)
        {
            dohash = false;
            dosort = true;
        }
        else if (phase->aggstrategy == AGG_HASHED)
        {
            dohash = true;
            dosort = false;
        }
        else
            Assert(false);

        phase->evaltrans = ExecBuildAggTrans(aggstate, phase, dosort, dohash,
                                             false);

        /* cache compiled expression for outer slot without NULL check */
        phase->evaltrans_cache[0][0] = phase->evaltrans;
    }

    return aggstate;
}

ExecReScanAgg()

void ExecReScanAgg

(

AggState *

node

)

Definition at line 4537 of file nodeAgg.c.

References AggState::agg_done, AGG_HASHED, AGG_MIXED, AggState::aggcontexts, Agg::aggParams, AggState::aggstrategy, bms_overlap(), build_hash_tables(), PlanState::chgParam, ExprContext::ecxt_aggnulls, ExprContext::ecxt_aggvalues, ExecClearTuple(), ExecReScan(), AggState::grp_firstTuple, AggState::hash_ever_spilled, AggState::hash_ngroups_current, AggState::hash_spill_mode, hashagg_recompile_expressions(), hashagg_reset_spill_state(), AggState::hashcontext, AggStatePerHashData::hashiter, AggStatePerHashData::hashtable, heap_freetuple(), initialize_phase(), AggState::input_done, Max, AggState::maxsets, MemSet, AggState::numaggs, AggState::numtrans, outerPlan, outerPlanState, AggState::pergroups, AggState::perhash, AggState::pertrans, PlanState::plan, AggState::projected_set, ScanState::ps, PlanState::ps_ExprContext, ReScanExprContext(), ResetTupleHashIterator, select_current_set(), AggStatePerTransData::sortstates, AggState::ss, ScanState::ss_ScanTupleSlot, AggState::table_filled, and tuplesort_end().

Referenced by ExecReScan().

{
    ExprContext *econtext = node->ss.ps.ps_ExprContext;
    PlanState  *outerPlan = outerPlanState(node);
    Agg        *aggnode = (Agg *) node->ss.ps.plan;
    int         transno;
    int         numGroupingSets = Max(node->maxsets, 1);
    int         setno;

    node->agg_done = false;

    if (node->aggstrategy == AGG_HASHED)
    {
        /*
         * In the hashed case, if we haven't yet built the hash table then we
         * can just return; nothing done yet, so nothing to undo. If subnode's
         * chgParam is not NULL then it will be re-scanned by ExecProcNode,
         * else no reason to re-scan it at all.
         */
        if (!node->table_filled)
            return;

        /*
         * If we do have the hash table, and it never spilled, and the subplan
         * does not have any parameter changes, and none of our own parameter
         * changes affect input expressions of the aggregated functions, then
         * we can just rescan the existing hash table; no need to build it
         * again.
         */
        if (outerPlan->chgParam == NULL && !node->hash_ever_spilled &&
            !bms_overlap(node->ss.ps.chgParam, aggnode->aggParams))
        {
            ResetTupleHashIterator(node->perhash[0].hashtable,
                                   &node->perhash[0].hashiter);
            select_current_set(node, 0, true);
            return;
        }
    }

    /* Make sure we have closed any open tuplesorts */
    for (transno = 0; transno < node->numtrans; transno++)
    {
        for (setno = 0; setno < numGroupingSets; setno++)
        {
            AggStatePerTrans pertrans = &node->pertrans[transno];

            if (pertrans->sortstates[setno])
            {
                tuplesort_end(pertrans->sortstates[setno]);
                pertrans->sortstates[setno] = NULL;
            }
        }
    }

    /*
     * We don't need to ReScanExprContext the output tuple context here;
     * ExecReScan already did it. But we do need to reset our per-grouping-set
     * contexts, which may have transvalues stored in them. (We use rescan
     * rather than just reset because transfns may have registered callbacks
     * that need to be run now.) For the AGG_HASHED case, see below.
     */

    for (setno = 0; setno < numGroupingSets; setno++)
    {
        ReScanExprContext(node->aggcontexts[setno]);
    }

    /* Release first tuple of group, if we have made a copy */
    if (node->grp_firstTuple != NULL)
    {
        heap_freetuple(node->grp_firstTuple);
        node->grp_firstTuple = NULL;
    }
    ExecClearTuple(node->ss.ss_ScanTupleSlot);

    /* Forget current agg values */
    MemSet(econtext->ecxt_aggvalues, 0, sizeof(Datum) * node->numaggs);
    MemSet(econtext->ecxt_aggnulls, 0, sizeof(bool) * node->numaggs);

    /*
     * With AGG_HASHED/MIXED, the hash table is allocated in a sub-context of
     * the hashcontext. This used to be an issue, but now, resetting a context
     * automatically deletes sub-contexts too.
     */
    if (node->aggstrategy == AGG_HASHED || node->aggstrategy == AGG_MIXED)
    {
        hashagg_reset_spill_state(node);

        node->hash_ever_spilled = false;
        node->hash_spill_mode = false;
        node->hash_ngroups_current = 0;

        ReScanExprContext(node->hashcontext);
        /* Rebuild an empty hash table */
        build_hash_tables(node);
        node->table_filled = false;
        /* iterator will be reset when the table is filled */

        hashagg_recompile_expressions(node, false, false);
    }

    if (node->aggstrategy != AGG_HASHED)
    {
        /*
         * Reset the per-group state (in particular, mark transvalues null)
         */
        for (setno = 0; setno < numGroupingSets; setno++)
        {
            MemSet(node->pergroups[setno], 0,
                   sizeof(AggStatePerGroupData) * node->numaggs);
        }

        /* reset to phase 1 */
        initialize_phase(node, 1);

        node->input_done = false;
        node->projected_set = -1;
    }

    if (outerPlan->chgParam == NULL)
        ExecReScan(outerPlan);
}

hash_agg_entry_size()

Size hash_agg_entry_size	(	int	numTrans,
		Size	tupleWidth,
		Size	transitionSpace
	)

Definition at line 1649 of file nodeAgg.c.

References CHUNKHDRSZ, MAXALIGN, and SizeofMinimalTupleHeader.

Referenced by cost_agg(), create_distinct_paths(), estimate_hashagg_tablesize(), and ExecInitAgg().

{
    Size        tupleChunkSize;
    Size        pergroupChunkSize;
    Size        transitionChunkSize;
    Size        tupleSize = (MAXALIGN(SizeofMinimalTupleHeader) +
                             tupleWidth);
    Size        pergroupSize = numTrans * sizeof(AggStatePerGroupData);

    tupleChunkSize = CHUNKHDRSZ + tupleSize;

    if (pergroupSize > 0)
        pergroupChunkSize = CHUNKHDRSZ + pergroupSize;
    else
        pergroupChunkSize = 0;

    if (transitionSpace > 0)
        transitionChunkSize = CHUNKHDRSZ + transitionSpace;
    else
        transitionChunkSize = 0;

    return
        sizeof(TupleHashEntryData) +
        tupleChunkSize +
        pergroupChunkSize +
        transitionChunkSize;
}

hash_agg_set_limits()

void hash_agg_set_limits	(	double	hashentrysize,
		uint64	input_groups,
		int	used_bits,
		Size *	mem_limit,
		uint64 *	ngroups_limit,
		int *	num_partitions
	)

Definition at line 1747 of file nodeAgg.c.

References hash_choose_num_partitions(), HASHAGG_READ_BUFFER_SIZE, HASHAGG_WRITE_BUFFER_SIZE, and work_mem.

Referenced by agg_refill_hash_table(), cost_agg(), and ExecInitAgg().

{
    int         npartitions;
    Size        partition_mem;

    /* if not expected to spill, use all of work_mem */
    if (input_groups * hashentrysize < work_mem * 1024L)
    {
        if (num_partitions != NULL)
            *num_partitions = 0;
        *mem_limit = work_mem * 1024L;
        *ngroups_limit = *mem_limit / hashentrysize;
        return;
    }

    /*
     * Calculate expected memory requirements for spilling, which is the size
     * of the buffers needed for all the tapes that need to be open at once.
     * Then, subtract that from the memory available for holding hash tables.
     */
    npartitions = hash_choose_num_partitions(input_groups,
                                             hashentrysize,
                                             used_bits,
                                             NULL);
    if (num_partitions != NULL)
        *num_partitions = npartitions;

    partition_mem =
        HASHAGG_READ_BUFFER_SIZE +
        HASHAGG_WRITE_BUFFER_SIZE * npartitions;

    /*
     * Don't set the limit below 3/4 of work_mem. In that case, we are at the
     * minimum number of partitions, so we aren't going to dramatically exceed
     * work mem anyway.
     */
    if (work_mem * 1024L > 4 * partition_mem)
        *mem_limit = work_mem * 1024L - partition_mem;
    else
        *mem_limit = work_mem * 1024L * 0.75;

    if (*mem_limit > hashentrysize)
        *ngroups_limit = *mem_limit / hashentrysize;
    else
        *ngroups_limit = 1;
}