#include "access/parallel.h"
#include "nodes/execnodes.h"

Include dependency graph for nodeAgg.h:

This graph shows which files directly or indirectly include 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, double input_groups, int used_bits, Size mem_limit, uint64 ngroups_limit, int *num_partitions)

void	ExecAggEstimate (AggState node, ParallelContext pcxt)

void	ExecAggInitializeDSM (AggState node, ParallelContext pcxt)

void	ExecAggInitializeWorker (AggState node, ParallelWorkerContext pwcxt)

void	ExecAggRetrieveInstrumentation (AggState *node)

Macro Definition Documentation

◆ FIELDNO_AGGSTATEPERGROUPDATA_NOTRANSVALUE

#define FIELDNO_AGGSTATEPERGROUPDATA_NOTRANSVALUE 2

Definition at line 257 of file nodeAgg.h.

◆ FIELDNO_AGGSTATEPERGROUPDATA_TRANSVALUE

#define FIELDNO_AGGSTATEPERGROUPDATA_TRANSVALUE 0

Definition at line 252 of file nodeAgg.h.

◆ FIELDNO_AGGSTATEPERGROUPDATA_TRANSVALUEISNULL

#define FIELDNO_AGGSTATEPERGROUPDATA_TRANSVALUEISNULL 1

Definition at line 254 of file nodeAgg.h.

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

◆ ExecAggEstimate()

void ExecAggEstimate	(	AggState *	node,
		ParallelContext *	pcxt
	)

Definition at line 4779 of file nodeAgg.c.

{
    Size        size;
 
    /* don't need this if not instrumenting or no workers */
    if (!node->ss.ps.instrument || pcxt->nworkers == 0)
        return;
 
    size = mul_size(pcxt->nworkers, sizeof(AggregateInstrumentation));
    size = add_size(size, offsetof(SharedAggInfo, sinstrument));
    shm_toc_estimate_chunk(&pcxt->estimator, size);
    shm_toc_estimate_keys(&pcxt->estimator, 1);
}

References add_size(), ParallelContext::estimator, PlanState::instrument, mul_size(), ParallelContext::nworkers, ScanState::ps, shm_toc_estimate_chunk, shm_toc_estimate_keys, and AggState::ss.

Referenced by ExecParallelEstimate().

◆ ExecAggInitializeDSM()

void ExecAggInitializeDSM	(	AggState *	node,
		ParallelContext *	pcxt
	)

Definition at line 4800 of file nodeAgg.c.

{
    Size        size;
 
    /* don't need this if not instrumenting or no workers */
    if (!node->ss.ps.instrument || pcxt->nworkers == 0)
        return;
 
    size = offsetof(SharedAggInfo, sinstrument)
        + pcxt->nworkers * sizeof(AggregateInstrumentation);
    node->shared_info = shm_toc_allocate(pcxt->toc, size);
    /* ensure any unfilled slots will contain zeroes */
    memset(node->shared_info, 0, size);
    node->shared_info->num_workers = pcxt->nworkers;
    shm_toc_insert(pcxt->toc, node->ss.ps.plan->plan_node_id,
                   node->shared_info);
}

References PlanState::instrument, SharedAggInfo::num_workers, ParallelContext::nworkers, PlanState::plan, Plan::plan_node_id, ScanState::ps, AggState::shared_info, shm_toc_allocate(), shm_toc_insert(), AggState::ss, and ParallelContext::toc.

Referenced by ExecParallelInitializeDSM().

◆ ExecAggInitializeWorker()

void ExecAggInitializeWorker	(	AggState *	node,
		ParallelWorkerContext *	pwcxt
	)

Definition at line 4825 of file nodeAgg.c.

{
    node->shared_info =
        shm_toc_lookup(pwcxt->toc, node->ss.ps.plan->plan_node_id, true);
}

References PlanState::plan, Plan::plan_node_id, ScanState::ps, AggState::shared_info, shm_toc_lookup(), AggState::ss, and ParallelWorkerContext::toc.

Referenced by ExecParallelInitializeWorker().

◆ ExecAggRetrieveInstrumentation()

void ExecAggRetrieveInstrumentation ( AggState * node )

Definition at line 4838 of file nodeAgg.c.

{
    Size        size;
    SharedAggInfo *si;
 
    if (node->shared_info == NULL)
        return;
 
    size = offsetof(SharedAggInfo, sinstrument)
        + node->shared_info->num_workers * sizeof(AggregateInstrumentation);
    si = palloc(size);
    memcpy(si, node->shared_info, size);
    node->shared_info = si;
}

References SharedAggInfo::num_workers, palloc(), and AggState::shared_info.

Referenced by ExecParallelRetrieveInstrumentation().

◆ ExecEndAgg()

void ExecEndAgg ( AggState * node )

Definition at line 4394 of file nodeAgg.c.

{
    PlanState  *outerPlan;
    int         transno;
    int         numGroupingSets = Max(node->maxsets, 1);
    int         setno;
 
    /*
     * When ending a parallel worker, copy the statistics gathered by the
     * worker back into shared memory so that it can be picked up by the main
     * process to report in EXPLAIN ANALYZE.
     */
    if (node->shared_info && IsParallelWorker())
    {
        AggregateInstrumentation *si;
 
        Assert(ParallelWorkerNumber <= node->shared_info->num_workers);
        si = &node->shared_info->sinstrument[ParallelWorkerNumber];
        si->hash_batches_used = node->hash_batches_used;
        si->hash_disk_used = node->hash_disk_used;
        si->hash_mem_peak = node->hash_mem_peak;
    }
 
    /* 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);
 
    /* Release hash tables too */
    if (node->hash_metacxt != NULL)
    {
        MemoryContextDelete(node->hash_metacxt);
        node->hash_metacxt = NULL;
    }
    if (node->hash_tuplescxt != NULL)
    {
        MemoryContextDelete(node->hash_tuplescxt);
        node->hash_tuplescxt = 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);
 
    outerPlan = outerPlanState(node);
    ExecEndNode(outerPlan);
}

References AggState::aggcontexts, Assert(), ExecEndNode(), AggregateInstrumentation::hash_batches_used, AggState::hash_batches_used, AggregateInstrumentation::hash_disk_used, AggState::hash_disk_used, AggregateInstrumentation::hash_mem_peak, AggState::hash_mem_peak, AggState::hash_metacxt, AggState::hash_tuplescxt, hashagg_reset_spill_state(), AggState::hashcontext, IsParallelWorker, Max, AggState::maxsets, MemoryContextDelete(), AggState::numtrans, outerPlan, outerPlanState, ParallelWorkerNumber, AggState::pertrans, ReScanExprContext(), AggState::shared_info, SharedAggInfo::sinstrument, AggState::sort_in, AggState::sort_out, AggStatePerTransData::sortstates, and tuplesort_end().

Referenced by ExecEndNode().

◆ ExecInitAgg()

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

Definition at line 3279 of file nodeAgg.c.

{
    AggState   *aggstate;
    AggStatePerAgg peraggs;
    AggStatePerTrans pertransstates;
    AggStatePerGroup *pergroups;
    Plan       *outerPlan;
    ExprContext *econtext;
    TupleDesc   scanDesc;
    int         max_aggno;
    int         max_transno;
    int         numaggrefs;
    int         numaggs;
    int         numtrans;
    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 = palloc0_array(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)
        hash_create_memory(aggstate);
 
    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 them to aggstate->aggs.
     * Aggrefs in the qual are found here; Aggrefs in the targetlist are found
     * during ExecAssignProjectionInfo, above.
     */
    aggstate->ss.ps.qual =
        ExecInitQual(node->plan.qual, (PlanState *) aggstate);
 
    /*
     * We should now have found all Aggrefs in the targetlist and quals.
     */
    numaggrefs = list_length(aggstate->aggs);
    max_aggno = -1;
    max_transno = -1;
    foreach(l, aggstate->aggs)
    {
        Aggref     *aggref = (Aggref *) lfirst(l);
 
        max_aggno = Max(max_aggno, aggref->aggno);
        max_transno = Max(max_transno, aggref->aggtransno);
    }
    aggstate->numaggs = numaggs = max_aggno + 1;
    aggstate->numtrans = numtrans = max_transno + 1;
 
    /*
     * For each phase, prepare grouping set data and fmgr lookup data for
     * compare functions.  Accumulate all_grouped_cols in passing.
     */
    aggstate->phases = palloc0_array(AggStatePerPhaseData, numPhases);
 
    aggstate->num_hashes = numHashes;
    if (numHashes)
    {
        aggstate->perhash = palloc0_array(AggStatePerHashData, numHashes);
        aggstate->phases[0].numsets = 0;
        aggstate->phases[0].gset_lengths = palloc_array(int, numHashes);
        aggstate->phases[0].grouped_cols = palloc_array(Bitmapset *, numHashes);
    }
 
    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, outerPlan(aggnode));
        }
        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)
            {
                /*
                 * Build a separate function for each subset of columns that
                 * need to be compared.
                 */
                phasedata->eqfunctions = palloc0_array(ExprState *, aggnode->numCols);
 
                /* for each grouping set */
                for (int k = 0; k < phasedata->numsets; k++)
                {
                    int         length = phasedata->gset_lengths[k];
 
                    /* nothing to do for empty grouping set */
                    if (length == 0)
                        continue;
 
                    /* if we already had one of this length, it'll do */
                    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 (aggnode->numCols > 0 &&
                    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 = palloc0_array(Datum, numaggs);
    econtext->ecxt_aggnulls = palloc0_array(bool, numaggs);
 
    peraggs = palloc0_array(AggStatePerAggData, numaggs);
    pertransstates = palloc0_array(AggStatePerTransData, numtrans);
 
    aggstate->peragg = peraggs;
    aggstate->pertrans = pertransstates;
 
 
    aggstate->all_pergroups = palloc0_array(AggStatePerGroup, numGroupingSets + numHashes);
    pergroups = aggstate->all_pergroups;
 
    if (node->aggstrategy != AGG_HASHED)
    {
        for (i = 0; i < numGroupingSets; i++)
        {
            pergroups[i] = palloc0_array(AggStatePerGroupData, numaggs);
        }
 
        aggstate->pergroups = pergroups;
        pergroups += numGroupingSets;
    }
 
    /*
     * Hashing can only appear in the initial phase.
     */
    if (use_hashing)
    {
        Plan       *outerplan = outerPlan(node);
        double      totalGroups = 0;
 
        aggstate->hash_spill_rslot = ExecInitExtraTupleSlot(estate, scanDesc,
                                                            &TTSOpsMinimalTuple);
        aggstate->hash_spill_wslot = ExecInitExtraTupleSlot(estate, scanDesc,
                                                            &TTSOpsVirtual);
 
        /* 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 (int k = 0; k < aggstate->num_hashes; k++)
            totalGroups += aggstate->perhash[k].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);
 
        /* Skip massive memory allocation if we are just doing EXPLAIN */
        if (!(eflags & EXEC_FLAG_EXPLAIN_ONLY))
            build_hash_tables(aggstate);
 
        aggstate->table_filled = false;
 
        /* Initialize this to 1, meaning nothing spilled, yet */
        aggstate->hash_batches_used = 1;
    }
 
    /*
     * 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.
     */
    foreach(l, aggstate->aggs)
    {
        Aggref     *aggref = lfirst(l);
        AggStatePerAgg peragg;
        AggStatePerTrans pertrans;
        Oid         aggTransFnInputTypes[FUNC_MAX_ARGS];
        int         numAggTransFnArgs;
        int         numDirectArgs;
        HeapTuple   aggTuple;
        Form_pg_aggregate aggform;
        AclResult   aclresult;
        Oid         finalfn_oid;
        Oid         serialfn_oid,
                    deserialfn_oid;
        Oid         aggOwner;
        Expr       *finalfnexpr;
        Oid         aggtranstype;
 
        /* Planner should have assigned aggregate to correct level */
        Assert(aggref->agglevelsup == 0);
        /* ... and the split mode should match */
        Assert(aggref->aggsplit == aggstate->aggsplit);
 
        peragg = &peraggs[aggref->aggno];
 
        /* Check if we initialized the state for this aggregate already. */
        if (peragg->aggref != NULL)
            continue;
 
        peragg->aggref = aggref;
        peragg->transno = aggref->aggtransno;
 
        /* 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 = object_aclcheck(ProcedureRelationId, 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));
 
        /* 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;
 
        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;
 
            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);
 
            if (OidIsValid(finalfn_oid))
            {
                aclresult = object_aclcheck(ProcedureRelationId, 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 = object_aclcheck(ProcedureRelationId, 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 = object_aclcheck(ProcedureRelationId, 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.
         */
        numAggTransFnArgs = get_aggregate_argtypes(aggref,
                                                   aggTransFnInputTypes);
 
        /* 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 = numAggTransFnArgs + 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(aggTransFnInputTypes,
                                         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);
 
        /*
         * Build working state for invoking the transition function, if we
         * haven't done it already.
         */
        pertrans = &pertransstates[aggref->aggtransno];
        if (pertrans->aggref == NULL)
        {
            Datum       textInitVal;
            Datum       initValue;
            bool        initValueIsNull;
            Oid         transfn_oid;
 
            /*
             * 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;
 
            aclresult = object_aclcheck(ProcedureRelationId, transfn_oid, aggOwner, ACL_EXECUTE);
            if (aclresult != ACLCHECK_OK)
                aclcheck_error(aclresult, OBJECT_FUNCTION,
                               get_func_name(transfn_oid));
            InvokeFunctionExecuteHook(transfn_oid);
 
            /*
             * 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);
 
            if (DO_AGGSPLIT_COMBINE(aggstate->aggsplit))
            {
                Oid         combineFnInputTypes[] = {aggtranstype,
                aggtranstype};
 
                /*
                 * When combining there's only one input, the to-be-combined
                 * transition value.  The transition value is not counted
                 * here.
                 */
                pertrans->numTransInputs = 1;
 
                /* aggcombinefn always has two arguments of aggtranstype */
                build_pertrans_for_aggref(pertrans, aggstate, estate,
                                          aggref, transfn_oid, aggtranstype,
                                          serialfn_oid, deserialfn_oid,
                                          initValue, initValueIsNull,
                                          combineFnInputTypes, 2);
 
                /*
                 * Ensure that a combine function to combine INTERNAL states
                 * is not strict. This should have been checked during CREATE
                 * AGGREGATE, but the strict property could have been changed
                 * since then.
                 */
                if (pertrans->transfn.fn_strict && aggtranstype == INTERNALOID)
                    ereport(ERROR,
                            (errcode(ERRCODE_INVALID_FUNCTION_DEFINITION),
                             errmsg("combine function with transition type %s must not be declared STRICT",
                                    format_type_be(aggtranstype))));
            }
            else
            {
                /* Detect how many arguments to pass to the transfn */
                if (AGGKIND_IS_ORDERED_SET(aggref->aggkind))
                    pertrans->numTransInputs = list_length(aggref->args);
                else
                    pertrans->numTransInputs = numAggTransFnArgs;
 
                build_pertrans_for_aggref(pertrans, aggstate, estate,
                                          aggref, transfn_oid, aggtranstype,
                                          serialfn_oid, deserialfn_oid,
                                          initValue, initValueIsNull,
                                          aggTransFnInputTypes,
                                          numAggTransFnArgs);
 
                /*
                 * If the transfn is strict and the initval is NULL, make sure
                 * input type and transtype are the same (or at least
                 * binary-compatible), so that it's OK to use the first
                 * aggregated input value as the initial transValue.  This
                 * should have been checked at agg definition time, but we
                 * must check again in case the transfn's strictness property
                 * has been changed.
                 */
                if (pertrans->transfn.fn_strict && pertrans->initValueIsNull)
                {
                    if (numAggTransFnArgs <= numDirectArgs ||
                        !IsBinaryCoercible(aggTransFnInputTypes[numDirectArgs],
                                           aggtranstype))
                        ereport(ERROR,
                                (errcode(ERRCODE_INVALID_FUNCTION_DEFINITION),
                                 errmsg("aggregate %u needs to have compatible input type and transition type",
                                        aggref->aggfnoid)));
                }
            }
        }
        else
            pertrans->aggshared = true;
        ReleaseSysCache(aggTuple);
    }
 
    /*
     * 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 (numaggrefs != 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;
}

Referenced by ExecInitNode().

◆ ExecReScanAgg()

void ExecReScanAgg ( AggState * node )

Definition at line 4460 of file nodeAgg.c.

{
    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 empty hash table(s) */
        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);
}

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().

◆ hash_agg_entry_size()

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

Definition at line 1698 of file nodeAgg.c.

{
    Size        tupleChunkSize;
    Size        pergroupChunkSize;
    Size        transitionChunkSize;
    Size        tupleSize = (MAXALIGN(SizeofMinimalTupleHeader) +
                             tupleWidth);
    Size        pergroupSize = numTrans * sizeof(AggStatePerGroupData);
 
    /*
     * Entries use the Bump allocator, so the chunk sizes are the same as the
     * requested sizes.
     */
    tupleChunkSize = MAXALIGN(tupleSize);
    pergroupChunkSize = pergroupSize;
 
    /*
     * Transition values use AllocSet, which has a chunk header and also uses
     * power-of-two allocations.
     */
    if (transitionSpace > 0)
        transitionChunkSize = CHUNKHDRSZ + pg_nextpower2_size_t(transitionSpace);
    else
        transitionChunkSize = 0;
 
    return
        TupleHashEntrySize() +
        tupleChunkSize +
        pergroupChunkSize +
        transitionChunkSize;
}

References CHUNKHDRSZ, MAXALIGN, pg_nextpower2_size_t, SizeofMinimalTupleHeader, and TupleHashEntrySize().

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

◆ hash_agg_set_limits()

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

Definition at line 1806 of file nodeAgg.c.

{
    int         npartitions;
    Size        partition_mem;
    Size        hash_mem_limit = get_hash_memory_limit();
 
    /* if not expected to spill, use all of hash_mem */
    if (input_groups * hashentrysize <= hash_mem_limit)
    {
        if (num_partitions != NULL)
            *num_partitions = 0;
        *mem_limit = hash_mem_limit;
        *ngroups_limit = hash_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 hash_mem. In that case, we are at the
     * minimum number of partitions, so we aren't going to dramatically exceed
     * work mem anyway.
     */
    if (hash_mem_limit > 4 * partition_mem)
        *mem_limit = hash_mem_limit - partition_mem;
    else
        *mem_limit = hash_mem_limit * 0.75;
 
    if (*mem_limit > hashentrysize)
        *ngroups_limit = *mem_limit / hashentrysize;
    else
        *ngroups_limit = 1;
}

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

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

Data Structures

Macros

Typedefs

Functions