nodeHash.c File Reference

#include "postgres.h"
#include <math.h>
#include <limits.h>
#include "access/htup_details.h"
#include "access/parallel.h"
#include "catalog/pg_statistic.h"
#include "commands/tablespace.h"
#include "executor/execdebug.h"
#include "executor/hashjoin.h"
#include "executor/nodeHash.h"
#include "executor/nodeHashjoin.h"
#include "miscadmin.h"
#include "pgstat.h"
#include "port/atomics.h"
#include "port/pg_bitutils.h"
#include "utils/dynahash.h"
#include "utils/guc.h"
#include "utils/lsyscache.h"
#include "utils/memutils.h"
#include "utils/syscache.h"

Include dependency graph for nodeHash.c:

Go to the source code of this file.

Macros
#define	NTUP_PER_BUCKET   1

Functions
static void	ExecHashIncreaseNumBatches (HashJoinTable hashtable)
static void	ExecHashIncreaseNumBuckets (HashJoinTable hashtable)
static void	ExecParallelHashIncreaseNumBatches (HashJoinTable hashtable)
static void	ExecParallelHashIncreaseNumBuckets (HashJoinTable hashtable)
static void	ExecHashBuildSkewHash (HashJoinTable hashtable, Hash *node, int mcvsToUse)
static void	ExecHashSkewTableInsert (HashJoinTable hashtable, TupleTableSlot *slot, uint32 hashvalue, int bucketNumber)
static void	ExecHashRemoveNextSkewBucket (HashJoinTable hashtable)
static void *	dense_alloc (HashJoinTable hashtable, Size size)
static HashJoinTuple	ExecParallelHashTupleAlloc (HashJoinTable hashtable, size_t size, dsa_pointer *shared)
static void	MultiExecPrivateHash (HashState *node)
static void	MultiExecParallelHash (HashState *node)
static HashJoinTuple	ExecParallelHashFirstTuple (HashJoinTable hashtable, int bucketno)
static HashJoinTuple	ExecParallelHashNextTuple (HashJoinTable hashtable, HashJoinTuple tuple)
static void	ExecParallelHashPushTuple (dsa_pointer_atomic *head, HashJoinTuple tuple, dsa_pointer tuple_shared)
static void	ExecParallelHashJoinSetUpBatches (HashJoinTable hashtable, int nbatch)
static void	ExecParallelHashEnsureBatchAccessors (HashJoinTable hashtable)
static void	ExecParallelHashRepartitionFirst (HashJoinTable hashtable)
static void	ExecParallelHashRepartitionRest (HashJoinTable hashtable)
static HashMemoryChunk	ExecParallelHashPopChunkQueue (HashJoinTable hashtable, dsa_pointer *shared)
static bool	ExecParallelHashTuplePrealloc (HashJoinTable hashtable, int batchno, size_t size)
static void	ExecParallelHashMergeCounters (HashJoinTable hashtable)
static void	ExecParallelHashCloseBatchAccessors (HashJoinTable hashtable)
static TupleTableSlot *	ExecHash (PlanState *pstate)
Node *	MultiExecHash (HashState *node)
HashState *	ExecInitHash (Hash *node, EState *estate, int eflags)
void	ExecEndHash (HashState *node)
HashJoinTable	ExecHashTableCreate (HashState *state, List *hashOperators, List *hashCollations, bool keepNulls)
void	ExecChooseHashTableSize (double ntuples, int tupwidth, bool useskew, bool try_combined_hash_mem, int parallel_workers, size_t *space_allowed, int *numbuckets, int *numbatches, int *num_skew_mcvs)
void	ExecHashTableDestroy (HashJoinTable hashtable)
void	ExecHashTableInsert (HashJoinTable hashtable, TupleTableSlot *slot, uint32 hashvalue)
void	ExecParallelHashTableInsert (HashJoinTable hashtable, TupleTableSlot *slot, uint32 hashvalue)
void	ExecParallelHashTableInsertCurrentBatch (HashJoinTable hashtable, TupleTableSlot *slot, uint32 hashvalue)
bool	ExecHashGetHashValue (HashJoinTable hashtable, ExprContext *econtext, List *hashkeys, bool outer_tuple, bool keep_nulls, uint32 *hashvalue)
void	ExecHashGetBucketAndBatch (HashJoinTable hashtable, uint32 hashvalue, int *bucketno, int *batchno)
bool	ExecScanHashBucket (HashJoinState *hjstate, ExprContext *econtext)
bool	ExecParallelScanHashBucket (HashJoinState *hjstate, ExprContext *econtext)
void	ExecPrepHashTableForUnmatched (HashJoinState *hjstate)
bool	ExecParallelPrepHashTableForUnmatched (HashJoinState *hjstate)
bool	ExecScanHashTableForUnmatched (HashJoinState *hjstate, ExprContext *econtext)
bool	ExecParallelScanHashTableForUnmatched (HashJoinState *hjstate, ExprContext *econtext)
void	ExecHashTableReset (HashJoinTable hashtable)
void	ExecHashTableResetMatchFlags (HashJoinTable hashtable)
void	ExecReScanHash (HashState *node)
int	ExecHashGetSkewBucket (HashJoinTable hashtable, uint32 hashvalue)
void	ExecHashEstimate (HashState *node, ParallelContext *pcxt)
void	ExecHashInitializeDSM (HashState *node, ParallelContext *pcxt)
void	ExecHashInitializeWorker (HashState *node, ParallelWorkerContext *pwcxt)
void	ExecShutdownHash (HashState *node)
void	ExecHashRetrieveInstrumentation (HashState *node)
void	ExecHashAccumInstrumentation (HashInstrumentation *instrument, HashJoinTable hashtable)
void	ExecParallelHashTableAlloc (HashJoinTable hashtable, int batchno)
void	ExecHashTableDetachBatch (HashJoinTable hashtable)
void	ExecHashTableDetach (HashJoinTable hashtable)
void	ExecParallelHashTableSetCurrentBatch (HashJoinTable hashtable, int batchno)
size_t	get_hash_memory_limit (void)

Macro Definition Documentation

NTUP_PER_BUCKET

#define NTUP_PER_BUCKET   1

Definition at line 678 of file nodeHash.c.

Function Documentation

dense_alloc()

static void * dense_alloc ( HashJoinTable  hashtable, Size  size  )

static

Definition at line 2866 of file nodeHash.c.

{
    HashMemoryChunk newChunk;
    char       *ptr;
 
    /* just in case the size is not already aligned properly */
    size = MAXALIGN(size);
 
    /*
     * If tuple size is larger than threshold, allocate a separate chunk.
     */
    if (size > HASH_CHUNK_THRESHOLD)
    {
        /* allocate new chunk and put it at the beginning of the list */
        newChunk = (HashMemoryChunk) MemoryContextAlloc(hashtable->batchCxt,
                                                        HASH_CHUNK_HEADER_SIZE + size);
        newChunk->maxlen = size;
        newChunk->used = size;
        newChunk->ntuples = 1;
 
        /*
         * Add this chunk to the list after the first existing chunk, so that
         * we don't lose the remaining space in the "current" chunk.
         */
        if (hashtable->chunks != NULL)
        {
            newChunk->next = hashtable->chunks->next;
            hashtable->chunks->next.unshared = newChunk;
        }
        else
        {
            newChunk->next.unshared = hashtable->chunks;
            hashtable->chunks = newChunk;
        }
 
        return HASH_CHUNK_DATA(newChunk);
    }
 
    /*
     * See if we have enough space for it in the current chunk (if any). If
     * not, allocate a fresh chunk.
     */
    if ((hashtable->chunks == NULL) ||
        (hashtable->chunks->maxlen - hashtable->chunks->used) < size)
    {
        /* allocate new chunk and put it at the beginning of the list */
        newChunk = (HashMemoryChunk) MemoryContextAlloc(hashtable->batchCxt,
                                                        HASH_CHUNK_HEADER_SIZE + HASH_CHUNK_SIZE);
 
        newChunk->maxlen = HASH_CHUNK_SIZE;
        newChunk->used = size;
        newChunk->ntuples = 1;
 
        newChunk->next.unshared = hashtable->chunks;
        hashtable->chunks = newChunk;
 
        return HASH_CHUNK_DATA(newChunk);
    }
 
    /* There is enough space in the current chunk, let's add the tuple */
    ptr = HASH_CHUNK_DATA(hashtable->chunks) + hashtable->chunks->used;
    hashtable->chunks->used += size;
    hashtable->chunks->ntuples += 1;
 
    /* return pointer to the start of the tuple memory */
    return ptr;
}

References HashJoinTableData::batchCxt, HashJoinTableData::chunks, HASH_CHUNK_DATA, HASH_CHUNK_HEADER_SIZE, HASH_CHUNK_SIZE, HASH_CHUNK_THRESHOLD, MAXALIGN, HashMemoryChunkData::maxlen, MemoryContextAlloc(), HashMemoryChunkData::next, HashMemoryChunkData::ntuples, HashMemoryChunkData::unshared, and HashMemoryChunkData::used.

Referenced by ExecHashIncreaseNumBatches(), ExecHashRemoveNextSkewBucket(), and ExecHashTableInsert().

ExecChooseHashTableSize()

void ExecChooseHashTableSize	(	double	ntuples,
		int	tupwidth,
		bool	useskew,
		bool	try_combined_hash_mem,
		int	parallel_workers,
		size_t *	space_allowed,
		int *	numbuckets,
		int *	numbatches,
		int *	num_skew_mcvs
	)

Definition at line 681 of file nodeHash.c.

{
    int         tupsize;
    double      inner_rel_bytes;
    size_t      hash_table_bytes;
    size_t      bucket_bytes;
    size_t      max_pointers;
    int         nbatch = 1;
    int         nbuckets;
    double      dbuckets;
 
    /* Force a plausible relation size if no info */
    if (ntuples <= 0.0)
        ntuples = 1000.0;
 
    /*
     * Estimate tupsize based on footprint of tuple in hashtable... note this
     * does not allow for any palloc overhead.  The manipulations of spaceUsed
     * don't count palloc overhead either.
     */
    tupsize = HJTUPLE_OVERHEAD +
        MAXALIGN(SizeofMinimalTupleHeader) +
        MAXALIGN(tupwidth);
    inner_rel_bytes = ntuples * tupsize;
 
    /*
     * Compute in-memory hashtable size limit from GUCs.
     */
    hash_table_bytes = get_hash_memory_limit();
 
    /*
     * Parallel Hash tries to use the combined hash_mem of all workers to
     * avoid the need to batch.  If that won't work, it falls back to hash_mem
     * per worker and tries to process batches in parallel.
     */
    if (try_combined_hash_mem)
    {
        /* Careful, this could overflow size_t */
        double      newlimit;
 
        newlimit = (double) hash_table_bytes * (double) (parallel_workers + 1);
        newlimit = Min(newlimit, (double) SIZE_MAX);
        hash_table_bytes = (size_t) newlimit;
    }
 
    *space_allowed = hash_table_bytes;
 
    /*
     * If skew optimization is possible, estimate the number of skew buckets
     * that will fit in the memory allowed, and decrement the assumed space
     * available for the main hash table accordingly.
     *
     * We make the optimistic assumption that each skew bucket will contain
     * one inner-relation tuple.  If that turns out to be low, we will recover
     * at runtime by reducing the number of skew buckets.
     *
     * hashtable->skewBucket will have up to 8 times as many HashSkewBucket
     * pointers as the number of MCVs we allow, since ExecHashBuildSkewHash
     * will round up to the next power of 2 and then multiply by 4 to reduce
     * collisions.
     */
    if (useskew)
    {
        size_t      bytes_per_mcv;
        size_t      skew_mcvs;
 
        /*----------
         * Compute number of MCVs we could hold in hash_table_bytes
         *
         * Divisor is:
         * size of a hash tuple +
         * worst-case size of skewBucket[] per MCV +
         * size of skewBucketNums[] entry +
         * size of skew bucket struct itself
         *----------
         */
        bytes_per_mcv = tupsize +
            (8 * sizeof(HashSkewBucket *)) +
            sizeof(int) +
            SKEW_BUCKET_OVERHEAD;
        skew_mcvs = hash_table_bytes / bytes_per_mcv;
 
        /*
         * Now scale by SKEW_HASH_MEM_PERCENT (we do it in this order so as
         * not to worry about size_t overflow in the multiplication)
         */
        skew_mcvs = (skew_mcvs * SKEW_HASH_MEM_PERCENT) / 100;
 
        /* Now clamp to integer range */
        skew_mcvs = Min(skew_mcvs, INT_MAX);
 
        *num_skew_mcvs = (int) skew_mcvs;
 
        /* Reduce hash_table_bytes by the amount needed for the skew table */
        if (skew_mcvs > 0)
            hash_table_bytes -= skew_mcvs * bytes_per_mcv;
    }
    else
        *num_skew_mcvs = 0;
 
    /*
     * Set nbuckets to achieve an average bucket load of NTUP_PER_BUCKET when
     * memory is filled, assuming a single batch; but limit the value so that
     * the pointer arrays we'll try to allocate do not exceed hash_table_bytes
     * nor MaxAllocSize.
     *
     * Note that both nbuckets and nbatch must be powers of 2 to make
     * ExecHashGetBucketAndBatch fast.
     */
    max_pointers = hash_table_bytes / sizeof(HashJoinTuple);
    max_pointers = Min(max_pointers, MaxAllocSize / sizeof(HashJoinTuple));
    /* If max_pointers isn't a power of 2, must round it down to one */
    max_pointers = pg_prevpower2_size_t(max_pointers);
 
    /* Also ensure we avoid integer overflow in nbatch and nbuckets */
    /* (this step is redundant given the current value of MaxAllocSize) */
    max_pointers = Min(max_pointers, INT_MAX / 2 + 1);
 
    dbuckets = ceil(ntuples / NTUP_PER_BUCKET);
    dbuckets = Min(dbuckets, max_pointers);
    nbuckets = (int) dbuckets;
    /* don't let nbuckets be really small, though ... */
    nbuckets = Max(nbuckets, 1024);
    /* ... and force it to be a power of 2. */
    nbuckets = pg_nextpower2_32(nbuckets);
 
    /*
     * If there's not enough space to store the projected number of tuples and
     * the required bucket headers, we will need multiple batches.
     */
    bucket_bytes = sizeof(HashJoinTuple) * nbuckets;
    if (inner_rel_bytes + bucket_bytes > hash_table_bytes)
    {
        /* We'll need multiple batches */
        size_t      sbuckets;
        double      dbatch;
        int         minbatch;
        size_t      bucket_size;
 
        /*
         * If Parallel Hash with combined hash_mem would still need multiple
         * batches, we'll have to fall back to regular hash_mem budget.
         */
        if (try_combined_hash_mem)
        {
            ExecChooseHashTableSize(ntuples, tupwidth, useskew,
                                    false, parallel_workers,
                                    space_allowed,
                                    numbuckets,
                                    numbatches,
                                    num_skew_mcvs);
            return;
        }
 
        /*
         * Estimate the number of buckets we'll want to have when hash_mem is
         * entirely full.  Each bucket will contain a bucket pointer plus
         * NTUP_PER_BUCKET tuples, whose projected size already includes
         * overhead for the hash code, pointer to the next tuple, etc.
         */
        bucket_size = (tupsize * NTUP_PER_BUCKET + sizeof(HashJoinTuple));
        if (hash_table_bytes <= bucket_size)
            sbuckets = 1;       /* avoid pg_nextpower2_size_t(0) */
        else
            sbuckets = pg_nextpower2_size_t(hash_table_bytes / bucket_size);
        sbuckets = Min(sbuckets, max_pointers);
        nbuckets = (int) sbuckets;
        nbuckets = pg_nextpower2_32(nbuckets);
        bucket_bytes = nbuckets * sizeof(HashJoinTuple);
 
        /*
         * Buckets are simple pointers to hashjoin tuples, while tupsize
         * includes the pointer, hash code, and MinimalTupleData.  So buckets
         * should never really exceed 25% of hash_mem (even for
         * NTUP_PER_BUCKET=1); except maybe for hash_mem values that are not
         * 2^N bytes, where we might get more because of doubling. So let's
         * look for 50% here.
         */
        Assert(bucket_bytes <= hash_table_bytes / 2);
 
        /* Calculate required number of batches. */
        dbatch = ceil(inner_rel_bytes / (hash_table_bytes - bucket_bytes));
        dbatch = Min(dbatch, max_pointers);
        minbatch = (int) dbatch;
        nbatch = pg_nextpower2_32(Max(2, minbatch));
    }
 
    Assert(nbuckets > 0);
    Assert(nbatch > 0);
 
    *numbuckets = nbuckets;
    *numbatches = nbatch;
}

References Assert(), get_hash_memory_limit(), HJTUPLE_OVERHEAD, Max, MAXALIGN, MaxAllocSize, Min, NTUP_PER_BUCKET, pg_nextpower2_32(), pg_nextpower2_size_t, pg_prevpower2_size_t, SizeofMinimalTupleHeader, SKEW_BUCKET_OVERHEAD, and SKEW_HASH_MEM_PERCENT.

Referenced by ExecHashTableCreate(), and initial_cost_hashjoin().

ExecEndHash()

void ExecEndHash

(

HashState *

node

)

Definition at line 414 of file nodeHash.c.

{
    PlanState  *outerPlan;
 
    /*
     * free exprcontext
     */
    ExecFreeExprContext(&node->ps);
 
    /*
     * shut down the subplan
     */
    outerPlan = outerPlanState(node);
    ExecEndNode(outerPlan);
}

References ExecEndNode(), ExecFreeExprContext(), outerPlan, outerPlanState, and HashState::ps.

Referenced by ExecEndNode().

ExecHash()

static TupleTableSlot* ExecHash ( PlanState *  pstate )

static

Definition at line 92 of file nodeHash.c.

{
    elog(ERROR, "Hash node does not support ExecProcNode call convention");
    return NULL;
}

References elog(), and ERROR.

Referenced by ExecInitHash().

ExecHashAccumInstrumentation()

void ExecHashAccumInstrumentation	(	HashInstrumentation *	instrument,
		HashJoinTable	hashtable
	)

Definition at line 2847 of file nodeHash.c.

{
    instrument->nbuckets = Max(instrument->nbuckets,
                               hashtable->nbuckets);
    instrument->nbuckets_original = Max(instrument->nbuckets_original,
                                        hashtable->nbuckets_original);
    instrument->nbatch = Max(instrument->nbatch,
                             hashtable->nbatch);
    instrument->nbatch_original = Max(instrument->nbatch_original,
                                      hashtable->nbatch_original);
    instrument->space_peak = Max(instrument->space_peak,
                                 hashtable->spacePeak);
}

References Max, HashJoinTableData::nbatch, HashInstrumentation::nbatch, HashJoinTableData::nbatch_original, HashInstrumentation::nbatch_original, HashJoinTableData::nbuckets, HashInstrumentation::nbuckets, HashJoinTableData::nbuckets_original, HashInstrumentation::nbuckets_original, HashInstrumentation::space_peak, and HashJoinTableData::spacePeak.

Referenced by ExecReScanHashJoin(), and ExecShutdownHash().

ExecHashBuildSkewHash()

static void ExecHashBuildSkewHash ( HashJoinTable  hashtable, Hash *  node, int  mcvsToUse  )

static

Definition at line 2372 of file nodeHash.c.

{
    HeapTupleData *statsTuple;
    AttStatsSlot sslot;
 
    /* Do nothing if planner didn't identify the outer relation's join key */
    if (!OidIsValid(node->skewTable))
        return;
    /* Also, do nothing if we don't have room for at least one skew bucket */
    if (mcvsToUse <= 0)
        return;
 
    /*
     * Try to find the MCV statistics for the outer relation's join key.
     */
    statsTuple = SearchSysCache3(STATRELATTINH,
                                 ObjectIdGetDatum(node->skewTable),
                                 Int16GetDatum(node->skewColumn),
                                 BoolGetDatum(node->skewInherit));
    if (!HeapTupleIsValid(statsTuple))
        return;
 
    if (get_attstatsslot(&sslot, statsTuple,
                         STATISTIC_KIND_MCV, InvalidOid,
                         ATTSTATSSLOT_VALUES | ATTSTATSSLOT_NUMBERS))
    {
        double      frac;
        int         nbuckets;
        FmgrInfo   *hashfunctions;
        int         i;
 
        if (mcvsToUse > sslot.nvalues)
            mcvsToUse = sslot.nvalues;
 
        /*
         * Calculate the expected fraction of outer relation that will
         * participate in the skew optimization.  If this isn't at least
         * SKEW_MIN_OUTER_FRACTION, don't use skew optimization.
         */
        frac = 0;
        for (i = 0; i < mcvsToUse; i++)
            frac += sslot.numbers[i];
        if (frac < SKEW_MIN_OUTER_FRACTION)
        {
            free_attstatsslot(&sslot);
            ReleaseSysCache(statsTuple);
            return;
        }
 
        /*
         * Okay, set up the skew hashtable.
         *
         * skewBucket[] is an open addressing hashtable with a power of 2 size
         * that is greater than the number of MCV values.  (This ensures there
         * will be at least one null entry, so searches will always
         * terminate.)
         *
         * Note: this code could fail if mcvsToUse exceeds INT_MAX/8 or
         * MaxAllocSize/sizeof(void *)/8, but that is not currently possible
         * since we limit pg_statistic entries to much less than that.
         */
        nbuckets = pg_nextpower2_32(mcvsToUse + 1);
        /* use two more bits just to help avoid collisions */
        nbuckets <<= 2;
 
        hashtable->skewEnabled = true;
        hashtable->skewBucketLen = nbuckets;
 
        /*
         * We allocate the bucket memory in the hashtable's batch context. It
         * is only needed during the first batch, and this ensures it will be
         * automatically removed once the first batch is done.
         */
        hashtable->skewBucket = (HashSkewBucket **)
            MemoryContextAllocZero(hashtable->batchCxt,
                                   nbuckets * sizeof(HashSkewBucket *));
        hashtable->skewBucketNums = (int *)
            MemoryContextAllocZero(hashtable->batchCxt,
                                   mcvsToUse * sizeof(int));
 
        hashtable->spaceUsed += nbuckets * sizeof(HashSkewBucket *)
            + mcvsToUse * sizeof(int);
        hashtable->spaceUsedSkew += nbuckets * sizeof(HashSkewBucket *)
            + mcvsToUse * sizeof(int);
        if (hashtable->spaceUsed > hashtable->spacePeak)
            hashtable->spacePeak = hashtable->spaceUsed;
 
        /*
         * Create a skew bucket for each MCV hash value.
         *
         * Note: it is very important that we create the buckets in order of
         * decreasing MCV frequency.  If we have to remove some buckets, they
         * must be removed in reverse order of creation (see notes in
         * ExecHashRemoveNextSkewBucket) and we want the least common MCVs to
         * be removed first.
         */
        hashfunctions = hashtable->outer_hashfunctions;
 
        for (i = 0; i < mcvsToUse; i++)
        {
            uint32      hashvalue;
            int         bucket;
 
            hashvalue = DatumGetUInt32(FunctionCall1Coll(&hashfunctions[0],
                                                         hashtable->collations[0],
                                                         sslot.values[i]));
 
            /*
             * While we have not hit a hole in the hashtable and have not hit
             * the desired bucket, we have collided with some previous hash
             * value, so try the next bucket location.  NB: this code must
             * match ExecHashGetSkewBucket.
             */
            bucket = hashvalue & (nbuckets - 1);
            while (hashtable->skewBucket[bucket] != NULL &&
                   hashtable->skewBucket[bucket]->hashvalue != hashvalue)
                bucket = (bucket + 1) & (nbuckets - 1);
 
            /*
             * If we found an existing bucket with the same hashvalue, leave
             * it alone.  It's okay for two MCVs to share a hashvalue.
             */
            if (hashtable->skewBucket[bucket] != NULL)
                continue;
 
            /* Okay, create a new skew bucket for this hashvalue. */
            hashtable->skewBucket[bucket] = (HashSkewBucket *)
                MemoryContextAlloc(hashtable->batchCxt,
                                   sizeof(HashSkewBucket));
            hashtable->skewBucket[bucket]->hashvalue = hashvalue;
            hashtable->skewBucket[bucket]->tuples = NULL;
            hashtable->skewBucketNums[hashtable->nSkewBuckets] = bucket;
            hashtable->nSkewBuckets++;
            hashtable->spaceUsed += SKEW_BUCKET_OVERHEAD;
            hashtable->spaceUsedSkew += SKEW_BUCKET_OVERHEAD;
            if (hashtable->spaceUsed > hashtable->spacePeak)
                hashtable->spacePeak = hashtable->spaceUsed;
        }
 
        free_attstatsslot(&sslot);
    }
 
    ReleaseSysCache(statsTuple);
}

References ATTSTATSSLOT_NUMBERS, ATTSTATSSLOT_VALUES, HashJoinTableData::batchCxt, BoolGetDatum(), HashJoinTableData::collations, DatumGetUInt32(), free_attstatsslot(), FunctionCall1Coll(), get_attstatsslot(), HashSkewBucket::hashvalue, HeapTupleIsValid, i, if(), Int16GetDatum(), InvalidOid, MemoryContextAlloc(), MemoryContextAllocZero(), HashJoinTableData::nSkewBuckets, AttStatsSlot::numbers, AttStatsSlot::nvalues, ObjectIdGetDatum(), OidIsValid, HashJoinTableData::outer_hashfunctions, pg_nextpower2_32(), ReleaseSysCache(), SearchSysCache3(), SKEW_BUCKET_OVERHEAD, SKEW_MIN_OUTER_FRACTION, HashJoinTableData::skewBucket, HashJoinTableData::skewBucketLen, HashJoinTableData::skewBucketNums, Hash::skewColumn, HashJoinTableData::skewEnabled, Hash::skewInherit, Hash::skewTable, HashJoinTableData::spacePeak, HashJoinTableData::spaceUsed, HashJoinTableData::spaceUsedSkew, STATRELATTINH, HashSkewBucket::tuples, and AttStatsSlot::values.

Referenced by ExecHashTableCreate().

ExecHashEstimate()

void ExecHashEstimate	(	HashState *	node,
		ParallelContext *	pcxt
	)

Definition at line 2731 of file nodeHash.c.

{
    size_t      size;
 
    /* don't need this if not instrumenting or no workers */
    if (!node->ps.instrument || pcxt->nworkers == 0)
        return;
 
    size = mul_size(pcxt->nworkers, sizeof(HashInstrumentation));
    size = add_size(size, offsetof(SharedHashInfo, hinstrument));
    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, HashState::ps, shm_toc_estimate_chunk, and shm_toc_estimate_keys.

Referenced by ExecParallelEstimate().

ExecHashGetBucketAndBatch()

void ExecHashGetBucketAndBatch	(	HashJoinTable	hashtable,
		uint32	hashvalue,
		int *	bucketno,
		int *	batchno
	)

Definition at line 1929 of file nodeHash.c.

{
    uint32      nbuckets = (uint32) hashtable->nbuckets;
    uint32      nbatch = (uint32) hashtable->nbatch;
 
    if (nbatch > 1)
    {
        *bucketno = hashvalue & (nbuckets - 1);
        *batchno = pg_rotate_right32(hashvalue,
                                     hashtable->log2_nbuckets) & (nbatch - 1);
    }
    else
    {
        *bucketno = hashvalue & (nbuckets - 1);
        *batchno = 0;
    }
}

References HashJoinTableData::log2_nbuckets, HashJoinTableData::nbatch, HashJoinTableData::nbuckets, and pg_rotate_right32().

Referenced by ExecHashIncreaseNumBatches(), ExecHashIncreaseNumBuckets(), ExecHashJoinImpl(), ExecHashRemoveNextSkewBucket(), ExecHashTableInsert(), ExecParallelHashIncreaseNumBuckets(), ExecParallelHashJoinPartitionOuter(), ExecParallelHashRepartitionFirst(), ExecParallelHashRepartitionRest(), ExecParallelHashTableInsert(), and ExecParallelHashTableInsertCurrentBatch().

ExecHashGetHashValue()

bool ExecHashGetHashValue	(	HashJoinTable	hashtable,
		ExprContext *	econtext,
		List *	hashkeys,
		bool	outer_tuple,
		bool	keep_nulls,
		uint32 *	hashvalue
	)

Definition at line 1821 of file nodeHash.c.

{
    uint32      hashkey = 0;
    FmgrInfo   *hashfunctions;
    ListCell   *hk;
    int         i = 0;
    MemoryContext oldContext;
 
    /*
     * We reset the eval context each time to reclaim any memory leaked in the
     * hashkey expressions.
     */
    ResetExprContext(econtext);
 
    oldContext = MemoryContextSwitchTo(econtext->ecxt_per_tuple_memory);
 
    if (outer_tuple)
        hashfunctions = hashtable->outer_hashfunctions;
    else
        hashfunctions = hashtable->inner_hashfunctions;
 
    foreach(hk, hashkeys)
    {
        ExprState  *keyexpr = (ExprState *) lfirst(hk);
        Datum       keyval;
        bool        isNull;
 
        /* combine successive hashkeys by rotating */
        hashkey = pg_rotate_left32(hashkey, 1);
 
        /*
         * Get the join attribute value of the tuple
         */
        keyval = ExecEvalExpr(keyexpr, econtext, &isNull);
 
        /*
         * If the attribute is NULL, and the join operator is strict, then
         * this tuple cannot pass the join qual so we can reject it
         * immediately (unless we're scanning the outside of an outer join, in
         * which case we must not reject it).  Otherwise we act like the
         * hashcode of NULL is zero (this will support operators that act like
         * IS NOT DISTINCT, though not any more-random behavior).  We treat
         * the hash support function as strict even if the operator is not.
         *
         * Note: currently, all hashjoinable operators must be strict since
         * the hash index AM assumes that.  However, it takes so little extra
         * code here to allow non-strict that we may as well do it.
         */
        if (isNull)
        {
            if (hashtable->hashStrict[i] && !keep_nulls)
            {
                MemoryContextSwitchTo(oldContext);
                return false;   /* cannot match */
            }
            /* else, leave hashkey unmodified, equivalent to hashcode 0 */
        }
        else
        {
            /* Compute the hash function */
            uint32      hkey;
 
            hkey = DatumGetUInt32(FunctionCall1Coll(&hashfunctions[i], hashtable->collations[i], keyval));
            hashkey ^= hkey;
        }
 
        i++;
    }
 
    MemoryContextSwitchTo(oldContext);
 
    *hashvalue = hashkey;
    return true;
}

References HashJoinTableData::collations, DatumGetUInt32(), ExprContext::ecxt_per_tuple_memory, ExecEvalExpr(), FunctionCall1Coll(), HashJoinTableData::hashStrict, i, HashJoinTableData::inner_hashfunctions, lfirst, MemoryContextSwitchTo(), HashJoinTableData::outer_hashfunctions, pg_rotate_left32(), and ResetExprContext.

Referenced by ExecHashJoinOuterGetTuple(), ExecParallelHashJoinOuterGetTuple(), ExecParallelHashJoinPartitionOuter(), MultiExecParallelHash(), and MultiExecPrivateHash().

ExecHashGetSkewBucket()

int ExecHashGetSkewBucket	(	HashJoinTable	hashtable,
		uint32	hashvalue
	)

Definition at line 2525 of file nodeHash.c.

{
    int         bucket;
 
    /*
     * Always return INVALID_SKEW_BUCKET_NO if not doing skew optimization (in
     * particular, this happens after the initial batch is done).
     */
    if (!hashtable->skewEnabled)
        return INVALID_SKEW_BUCKET_NO;
 
    /*
     * Since skewBucketLen is a power of 2, we can do a modulo by ANDing.
     */
    bucket = hashvalue & (hashtable->skewBucketLen - 1);
 
    /*
     * While we have not hit a hole in the hashtable and have not hit the
     * desired bucket, we have collided with some other hash value, so try the
     * next bucket location.
     */
    while (hashtable->skewBucket[bucket] != NULL &&
           hashtable->skewBucket[bucket]->hashvalue != hashvalue)
        bucket = (bucket + 1) & (hashtable->skewBucketLen - 1);
 
    /*
     * Found the desired bucket?
     */
    if (hashtable->skewBucket[bucket] != NULL)
        return bucket;
 
    /*
     * There must not be any hashtable entry for this hash value.
     */
    return INVALID_SKEW_BUCKET_NO;
}

References HashSkewBucket::hashvalue, INVALID_SKEW_BUCKET_NO, HashJoinTableData::skewBucket, HashJoinTableData::skewBucketLen, and HashJoinTableData::skewEnabled.

Referenced by ExecHashJoinImpl(), and MultiExecPrivateHash().

ExecHashIncreaseNumBatches()

static void ExecHashIncreaseNumBatches ( HashJoinTable  hashtable )

static

Definition at line 922 of file nodeHash.c.

{
    int         oldnbatch = hashtable->nbatch;
    int         curbatch = hashtable->curbatch;
    int         nbatch;
    long        ninmemory;
    long        nfreed;
    HashMemoryChunk oldchunks;
 
    /* do nothing if we've decided to shut off growth */
    if (!hashtable->growEnabled)
        return;
 
    /* safety check to avoid overflow */
    if (oldnbatch > Min(INT_MAX / 2, MaxAllocSize / (sizeof(void *) * 2)))
        return;
 
    nbatch = oldnbatch * 2;
    Assert(nbatch > 1);
 
#ifdef HJDEBUG
    printf("Hashjoin %p: increasing nbatch to %d because space = %zu\n",
           hashtable, nbatch, hashtable->spaceUsed);
#endif
 
    if (hashtable->innerBatchFile == NULL)
    {
        MemoryContext oldcxt = MemoryContextSwitchTo(hashtable->spillCxt);
 
        /* we had no file arrays before */
        hashtable->innerBatchFile = palloc0_array(BufFile *, nbatch);
        hashtable->outerBatchFile = palloc0_array(BufFile *, nbatch);
 
        MemoryContextSwitchTo(oldcxt);
 
        /* time to establish the temp tablespaces, too */
        PrepareTempTablespaces();
    }
    else
    {
        /* enlarge arrays and zero out added entries */
        hashtable->innerBatchFile = repalloc0_array(hashtable->innerBatchFile, BufFile *, oldnbatch, nbatch);
        hashtable->outerBatchFile = repalloc0_array(hashtable->outerBatchFile, BufFile *, oldnbatch, nbatch);
    }
 
    hashtable->nbatch = nbatch;
 
    /*
     * Scan through the existing hash table entries and dump out any that are
     * no longer of the current batch.
     */
    ninmemory = nfreed = 0;
 
    /* If know we need to resize nbuckets, we can do it while rebatching. */
    if (hashtable->nbuckets_optimal != hashtable->nbuckets)
    {
        /* we never decrease the number of buckets */
        Assert(hashtable->nbuckets_optimal > hashtable->nbuckets);
 
        hashtable->nbuckets = hashtable->nbuckets_optimal;
        hashtable->log2_nbuckets = hashtable->log2_nbuckets_optimal;
 
        hashtable->buckets.unshared =
            repalloc_array(hashtable->buckets.unshared,
                           HashJoinTuple, hashtable->nbuckets);
    }
 
    /*
     * We will scan through the chunks directly, so that we can reset the
     * buckets now and not have to keep track which tuples in the buckets have
     * already been processed. We will free the old chunks as we go.
     */
    memset(hashtable->buckets.unshared, 0,
           sizeof(HashJoinTuple) * hashtable->nbuckets);
    oldchunks = hashtable->chunks;
    hashtable->chunks = NULL;
 
    /* so, let's scan through the old chunks, and all tuples in each chunk */
    while (oldchunks != NULL)
    {
        HashMemoryChunk nextchunk = oldchunks->next.unshared;
 
        /* position within the buffer (up to oldchunks->used) */
        size_t      idx = 0;
 
        /* process all tuples stored in this chunk (and then free it) */
        while (idx < oldchunks->used)
        {
            HashJoinTuple hashTuple = (HashJoinTuple) (HASH_CHUNK_DATA(oldchunks) + idx);
            MinimalTuple tuple = HJTUPLE_MINTUPLE(hashTuple);
            int         hashTupleSize = (HJTUPLE_OVERHEAD + tuple->t_len);
            int         bucketno;
            int         batchno;
 
            ninmemory++;
            ExecHashGetBucketAndBatch(hashtable, hashTuple->hashvalue,
                                      &bucketno, &batchno);
 
            if (batchno == curbatch)
            {
                /* keep tuple in memory - copy it into the new chunk */
                HashJoinTuple copyTuple;
 
                copyTuple = (HashJoinTuple) dense_alloc(hashtable, hashTupleSize);
                memcpy(copyTuple, hashTuple, hashTupleSize);
 
                /* and add it back to the appropriate bucket */
                copyTuple->next.unshared = hashtable->buckets.unshared[bucketno];
                hashtable->buckets.unshared[bucketno] = copyTuple;
            }
            else
            {
                /* dump it out */
                Assert(batchno > curbatch);
                ExecHashJoinSaveTuple(HJTUPLE_MINTUPLE(hashTuple),
                                      hashTuple->hashvalue,
                                      &hashtable->innerBatchFile[batchno],
                                      hashtable);
 
                hashtable->spaceUsed -= hashTupleSize;
                nfreed++;
            }
 
            /* next tuple in this chunk */
            idx += MAXALIGN(hashTupleSize);
 
            /* allow this loop to be cancellable */
            CHECK_FOR_INTERRUPTS();
        }
 
        /* we're done with this chunk - free it and proceed to the next one */
        pfree(oldchunks);
        oldchunks = nextchunk;
    }
 
#ifdef HJDEBUG
    printf("Hashjoin %p: freed %ld of %ld tuples, space now %zu\n",
           hashtable, nfreed, ninmemory, hashtable->spaceUsed);
#endif
 
    /*
     * If we dumped out either all or none of the tuples in the table, disable
     * further expansion of nbatch.  This situation implies that we have
     * enough tuples of identical hashvalues to overflow spaceAllowed.
     * Increasing nbatch will not fix it since there's no way to subdivide the
     * group any more finely. We have to just gut it out and hope the server
     * has enough RAM.
     */
    if (nfreed == 0 || nfreed == ninmemory)
    {
        hashtable->growEnabled = false;
#ifdef HJDEBUG
        printf("Hashjoin %p: disabling further increase of nbatch\n",
               hashtable);
#endif
    }
}

References Assert(), HashJoinTableData::buckets, CHECK_FOR_INTERRUPTS, HashJoinTableData::chunks, HashJoinTableData::curbatch, dense_alloc(), ExecHashGetBucketAndBatch(), ExecHashJoinSaveTuple(), HashJoinTableData::growEnabled, HASH_CHUNK_DATA, HashJoinTupleData::hashvalue, HJTUPLE_MINTUPLE, HJTUPLE_OVERHEAD, idx(), HashJoinTableData::innerBatchFile, HashJoinTableData::log2_nbuckets, HashJoinTableData::log2_nbuckets_optimal, MAXALIGN, MaxAllocSize, MemoryContextSwitchTo(), Min, HashJoinTableData::nbatch, HashJoinTableData::nbuckets, HashJoinTableData::nbuckets_optimal, HashJoinTupleData::next, HashMemoryChunkData::next, HashJoinTableData::outerBatchFile, palloc0_array, pfree(), PrepareTempTablespaces(), printf, repalloc0_array, repalloc_array, HashJoinTableData::spaceUsed, HashJoinTableData::spillCxt, MinimalTupleData::t_len, HashJoinTupleData::unshared, HashMemoryChunkData::unshared, and HashJoinTableData::unshared.

Referenced by ExecHashSkewTableInsert(), and ExecHashTableInsert().

ExecHashIncreaseNumBuckets()

static void ExecHashIncreaseNumBuckets ( HashJoinTable  hashtable )

static

Definition at line 1459 of file nodeHash.c.

{
    HashMemoryChunk chunk;
 
    /* do nothing if not an increase (it's called increase for a reason) */
    if (hashtable->nbuckets >= hashtable->nbuckets_optimal)
        return;
 
#ifdef HJDEBUG
    printf("Hashjoin %p: increasing nbuckets %d => %d\n",
           hashtable, hashtable->nbuckets, hashtable->nbuckets_optimal);
#endif
 
    hashtable->nbuckets = hashtable->nbuckets_optimal;
    hashtable->log2_nbuckets = hashtable->log2_nbuckets_optimal;
 
    Assert(hashtable->nbuckets > 1);
    Assert(hashtable->nbuckets <= (INT_MAX / 2));
    Assert(hashtable->nbuckets == (1 << hashtable->log2_nbuckets));
 
    /*
     * Just reallocate the proper number of buckets - we don't need to walk
     * through them - we can walk the dense-allocated chunks (just like in
     * ExecHashIncreaseNumBatches, but without all the copying into new
     * chunks)
     */
    hashtable->buckets.unshared =
        repalloc_array(hashtable->buckets.unshared,
                       HashJoinTuple, hashtable->nbuckets);
 
    memset(hashtable->buckets.unshared, 0,
           hashtable->nbuckets * sizeof(HashJoinTuple));
 
    /* scan through all tuples in all chunks to rebuild the hash table */
    for (chunk = hashtable->chunks; chunk != NULL; chunk = chunk->next.unshared)
    {
        /* process all tuples stored in this chunk */
        size_t      idx = 0;
 
        while (idx < chunk->used)
        {
            HashJoinTuple hashTuple = (HashJoinTuple) (HASH_CHUNK_DATA(chunk) + idx);
            int         bucketno;
            int         batchno;
 
            ExecHashGetBucketAndBatch(hashtable, hashTuple->hashvalue,
                                      &bucketno, &batchno);
 
            /* add the tuple to the proper bucket */
            hashTuple->next.unshared = hashtable->buckets.unshared[bucketno];
            hashtable->buckets.unshared[bucketno] = hashTuple;
 
            /* advance index past the tuple */
            idx += MAXALIGN(HJTUPLE_OVERHEAD +
                            HJTUPLE_MINTUPLE(hashTuple)->t_len);
        }
 
        /* allow this loop to be cancellable */
        CHECK_FOR_INTERRUPTS();
    }
}

References Assert(), HashJoinTableData::buckets, CHECK_FOR_INTERRUPTS, HashJoinTableData::chunks, ExecHashGetBucketAndBatch(), HASH_CHUNK_DATA, HashJoinTupleData::hashvalue, HJTUPLE_MINTUPLE, HJTUPLE_OVERHEAD, idx(), HashJoinTableData::log2_nbuckets, HashJoinTableData::log2_nbuckets_optimal, MAXALIGN, HashJoinTableData::nbuckets, HashJoinTableData::nbuckets_optimal, HashJoinTupleData::next, HashMemoryChunkData::next, printf, repalloc_array, HashJoinTupleData::unshared, HashMemoryChunkData::unshared, and HashJoinTableData::unshared.

Referenced by MultiExecPrivateHash().

ExecHashInitializeDSM()

void ExecHashInitializeDSM	(	HashState *	node,
		ParallelContext *	pcxt
	)

Definition at line 2750 of file nodeHash.c.

{
    size_t      size;
 
    /* don't need this if not instrumenting or no workers */
    if (!node->ps.instrument || pcxt->nworkers == 0)
        return;
 
    size = offsetof(SharedHashInfo, hinstrument) +
        pcxt->nworkers * sizeof(HashInstrumentation);
    node->shared_info = (SharedHashInfo *) shm_toc_allocate(pcxt->toc, size);
 
    /* Each per-worker area must start out as zeroes. */
    memset(node->shared_info, 0, size);
 
    node->shared_info->num_workers = pcxt->nworkers;
    shm_toc_insert(pcxt->toc, node->ps.plan->plan_node_id,
                   node->shared_info);
}

References PlanState::instrument, SharedHashInfo::num_workers, ParallelContext::nworkers, PlanState::plan, Plan::plan_node_id, HashState::ps, HashState::shared_info, shm_toc_allocate(), shm_toc_insert(), and ParallelContext::toc.

Referenced by ExecParallelInitializeDSM().

ExecHashInitializeWorker()

void ExecHashInitializeWorker	(	HashState *	node,
		ParallelWorkerContext *	pwcxt
	)

Definition at line 2775 of file nodeHash.c.

{
    SharedHashInfo *shared_info;
 
    /* don't need this if not instrumenting */
    if (!node->ps.instrument)
        return;
 
    /*
     * Find our entry in the shared area, and set up a pointer to it so that
     * we'll accumulate stats there when shutting down or rebuilding the hash
     * table.
     */
    shared_info = (SharedHashInfo *)
        shm_toc_lookup(pwcxt->toc, node->ps.plan->plan_node_id, false);
    node->hinstrument = &shared_info->hinstrument[ParallelWorkerNumber];
}

References SharedHashInfo::hinstrument, HashState::hinstrument, PlanState::instrument, ParallelWorkerNumber, PlanState::plan, Plan::plan_node_id, HashState::ps, shm_toc_lookup(), and ParallelWorkerContext::toc.

Referenced by ExecParallelInitializeWorker().

ExecHashRemoveNextSkewBucket()

static void ExecHashRemoveNextSkewBucket ( HashJoinTable  hashtable )

static

Definition at line 2617 of file nodeHash.c.

{
    int         bucketToRemove;
    HashSkewBucket *bucket;
    uint32      hashvalue;
    int         bucketno;
    int         batchno;
    HashJoinTuple hashTuple;
 
    /* Locate the bucket to remove */
    bucketToRemove = hashtable->skewBucketNums[hashtable->nSkewBuckets - 1];
    bucket = hashtable->skewBucket[bucketToRemove];
 
    /*
     * Calculate which bucket and batch the tuples belong to in the main
     * hashtable.  They all have the same hash value, so it's the same for all
     * of them.  Also note that it's not possible for nbatch to increase while
     * we are processing the tuples.
     */
    hashvalue = bucket->hashvalue;
    ExecHashGetBucketAndBatch(hashtable, hashvalue, &bucketno, &batchno);
 
    /* Process all tuples in the bucket */
    hashTuple = bucket->tuples;
    while (hashTuple != NULL)
    {
        HashJoinTuple nextHashTuple = hashTuple->next.unshared;
        MinimalTuple tuple;
        Size        tupleSize;
 
        /*
         * This code must agree with ExecHashTableInsert.  We do not use
         * ExecHashTableInsert directly as ExecHashTableInsert expects a
         * TupleTableSlot while we already have HashJoinTuples.
         */
        tuple = HJTUPLE_MINTUPLE(hashTuple);
        tupleSize = HJTUPLE_OVERHEAD + tuple->t_len;
 
        /* Decide whether to put the tuple in the hash table or a temp file */
        if (batchno == hashtable->curbatch)
        {
            /* Move the tuple to the main hash table */
            HashJoinTuple copyTuple;
 
            /*
             * We must copy the tuple into the dense storage, else it will not
             * be found by, eg, ExecHashIncreaseNumBatches.
             */
            copyTuple = (HashJoinTuple) dense_alloc(hashtable, tupleSize);
            memcpy(copyTuple, hashTuple, tupleSize);
            pfree(hashTuple);
 
            copyTuple->next.unshared = hashtable->buckets.unshared[bucketno];
            hashtable->buckets.unshared[bucketno] = copyTuple;
 
            /* We have reduced skew space, but overall space doesn't change */
            hashtable->spaceUsedSkew -= tupleSize;
        }
        else
        {
            /* Put the tuple into a temp file for later batches */
            Assert(batchno > hashtable->curbatch);
            ExecHashJoinSaveTuple(tuple, hashvalue,
                                  &hashtable->innerBatchFile[batchno],
                                  hashtable);
            pfree(hashTuple);
            hashtable->spaceUsed -= tupleSize;
            hashtable->spaceUsedSkew -= tupleSize;
        }
 
        hashTuple = nextHashTuple;
 
        /* allow this loop to be cancellable */
        CHECK_FOR_INTERRUPTS();
    }
 
    /*
     * Free the bucket struct itself and reset the hashtable entry to NULL.
     *
     * NOTE: this is not nearly as simple as it looks on the surface, because
     * of the possibility of collisions in the hashtable.  Suppose that hash
     * values A and B collide at a particular hashtable entry, and that A was
     * entered first so B gets shifted to a different table entry.  If we were
     * to remove A first then ExecHashGetSkewBucket would mistakenly start
     * reporting that B is not in the hashtable, because it would hit the NULL
     * before finding B.  However, we always remove entries in the reverse
     * order of creation, so this failure cannot happen.
     */
    hashtable->skewBucket[bucketToRemove] = NULL;
    hashtable->nSkewBuckets--;
    pfree(bucket);
    hashtable->spaceUsed -= SKEW_BUCKET_OVERHEAD;
    hashtable->spaceUsedSkew -= SKEW_BUCKET_OVERHEAD;
 
    /*
     * If we have removed all skew buckets then give up on skew optimization.
     * Release the arrays since they aren't useful any more.
     */
    if (hashtable->nSkewBuckets == 0)
    {
        hashtable->skewEnabled = false;
        pfree(hashtable->skewBucket);
        pfree(hashtable->skewBucketNums);
        hashtable->skewBucket = NULL;
        hashtable->skewBucketNums = NULL;
        hashtable->spaceUsed -= hashtable->spaceUsedSkew;
        hashtable->spaceUsedSkew = 0;
    }
}

References Assert(), HashJoinTableData::buckets, CHECK_FOR_INTERRUPTS, HashJoinTableData::curbatch, dense_alloc(), ExecHashGetBucketAndBatch(), ExecHashJoinSaveTuple(), HashSkewBucket::hashvalue, HJTUPLE_MINTUPLE, HJTUPLE_OVERHEAD, HashJoinTableData::innerBatchFile, HashJoinTupleData::next, HashJoinTableData::nSkewBuckets, pfree(), SKEW_BUCKET_OVERHEAD, HashJoinTableData::skewBucket, HashJoinTableData::skewBucketNums, HashJoinTableData::skewEnabled, HashJoinTableData::spaceUsed, HashJoinTableData::spaceUsedSkew, MinimalTupleData::t_len, HashSkewBucket::tuples, HashJoinTupleData::unshared, and HashJoinTableData::unshared.

Referenced by ExecHashSkewTableInsert().

ExecHashRetrieveInstrumentation()

void ExecHashRetrieveInstrumentation

(

HashState *

node

)

Definition at line 2816 of file nodeHash.c.

{
    SharedHashInfo *shared_info = node->shared_info;
    size_t      size;
 
    if (shared_info == NULL)
        return;
 
    /* Replace node->shared_info with a copy in backend-local memory. */
    size = offsetof(SharedHashInfo, hinstrument) +
        shared_info->num_workers * sizeof(HashInstrumentation);
    node->shared_info = palloc(size);
    memcpy(node->shared_info, shared_info, size);
}

References SharedHashInfo::num_workers, palloc(), and HashState::shared_info.

Referenced by ExecParallelRetrieveInstrumentation().

ExecHashSkewTableInsert()

static void ExecHashSkewTableInsert ( HashJoinTable  hashtable, TupleTableSlot *  slot, uint32  hashvalue, int  bucketNumber  )

static

Definition at line 2571 of file nodeHash.c.

{
    bool        shouldFree;
    MinimalTuple tuple = ExecFetchSlotMinimalTuple(slot, &shouldFree);
    HashJoinTuple hashTuple;
    int         hashTupleSize;
 
    /* Create the HashJoinTuple */
    hashTupleSize = HJTUPLE_OVERHEAD + tuple->t_len;
    hashTuple = (HashJoinTuple) MemoryContextAlloc(hashtable->batchCxt,
                                                   hashTupleSize);
    hashTuple->hashvalue = hashvalue;
    memcpy(HJTUPLE_MINTUPLE(hashTuple), tuple, tuple->t_len);
    HeapTupleHeaderClearMatch(HJTUPLE_MINTUPLE(hashTuple));
 
    /* Push it onto the front of the skew bucket's list */
    hashTuple->next.unshared = hashtable->skewBucket[bucketNumber]->tuples;
    hashtable->skewBucket[bucketNumber]->tuples = hashTuple;
    Assert(hashTuple != hashTuple->next.unshared);
 
    /* Account for space used, and back off if we've used too much */
    hashtable->spaceUsed += hashTupleSize;
    hashtable->spaceUsedSkew += hashTupleSize;
    if (hashtable->spaceUsed > hashtable->spacePeak)
        hashtable->spacePeak = hashtable->spaceUsed;
    while (hashtable->spaceUsedSkew > hashtable->spaceAllowedSkew)
        ExecHashRemoveNextSkewBucket(hashtable);
 
    /* Check we are not over the total spaceAllowed, either */
    if (hashtable->spaceUsed > hashtable->spaceAllowed)
        ExecHashIncreaseNumBatches(hashtable);
 
    if (shouldFree)
        heap_free_minimal_tuple(tuple);
}

References Assert(), HashJoinTableData::batchCxt, ExecFetchSlotMinimalTuple(), ExecHashIncreaseNumBatches(), ExecHashRemoveNextSkewBucket(), HashJoinTupleData::hashvalue, heap_free_minimal_tuple(), HeapTupleHeaderClearMatch, HJTUPLE_MINTUPLE, HJTUPLE_OVERHEAD, MemoryContextAlloc(), HashJoinTupleData::next, HashJoinTableData::skewBucket, HashJoinTableData::spaceAllowed, HashJoinTableData::spaceAllowedSkew, HashJoinTableData::spacePeak, HashJoinTableData::spaceUsed, HashJoinTableData::spaceUsedSkew, MinimalTupleData::t_len, HashSkewBucket::tuples, and HashJoinTupleData::unshared.

Referenced by MultiExecPrivateHash().

ExecHashTableCreate()

HashJoinTable ExecHashTableCreate	(	HashState *	state,
		List *	hashOperators,
		List *	hashCollations,
		bool	keepNulls
	)

Definition at line 438 of file nodeHash.c.

{
    Hash       *node;
    HashJoinTable hashtable;
    Plan       *outerNode;
    size_t      space_allowed;
    int         nbuckets;
    int         nbatch;
    double      rows;
    int         num_skew_mcvs;
    int         log2_nbuckets;
    int         nkeys;
    int         i;
    ListCell   *ho;
    ListCell   *hc;
    MemoryContext oldcxt;
 
    /*
     * Get information about the size of the relation to be hashed (it's the
     * "outer" subtree of this node, but the inner relation of the hashjoin).
     * Compute the appropriate size of the hash table.
     */
    node = (Hash *) state->ps.plan;
    outerNode = outerPlan(node);
 
    /*
     * If this is shared hash table with a partial plan, then we can't use
     * outerNode->plan_rows to estimate its size.  We need an estimate of the
     * total number of rows across all copies of the partial plan.
     */
    rows = node->plan.parallel_aware ? node->rows_total : outerNode->plan_rows;
 
    ExecChooseHashTableSize(rows, outerNode->plan_width,
                            OidIsValid(node->skewTable),
                            state->parallel_state != NULL,
                            state->parallel_state != NULL ?
                            state->parallel_state->nparticipants - 1 : 0,
                            &space_allowed,
                            &nbuckets, &nbatch, &num_skew_mcvs);
 
    /* nbuckets must be a power of 2 */
    log2_nbuckets = my_log2(nbuckets);
    Assert(nbuckets == (1 << log2_nbuckets));
 
    /*
     * Initialize the hash table control block.
     *
     * The hashtable control block is just palloc'd from the executor's
     * per-query memory context.  Everything else should be kept inside the
     * subsidiary hashCxt, batchCxt or spillCxt.
     */
    hashtable = palloc_object(HashJoinTableData);
    hashtable->nbuckets = nbuckets;
    hashtable->nbuckets_original = nbuckets;
    hashtable->nbuckets_optimal = nbuckets;
    hashtable->log2_nbuckets = log2_nbuckets;
    hashtable->log2_nbuckets_optimal = log2_nbuckets;
    hashtable->buckets.unshared = NULL;
    hashtable->keepNulls = keepNulls;
    hashtable->skewEnabled = false;
    hashtable->skewBucket = NULL;
    hashtable->skewBucketLen = 0;
    hashtable->nSkewBuckets = 0;
    hashtable->skewBucketNums = NULL;
    hashtable->nbatch = nbatch;
    hashtable->curbatch = 0;
    hashtable->nbatch_original = nbatch;
    hashtable->nbatch_outstart = nbatch;
    hashtable->growEnabled = true;
    hashtable->totalTuples = 0;
    hashtable->partialTuples = 0;
    hashtable->skewTuples = 0;
    hashtable->innerBatchFile = NULL;
    hashtable->outerBatchFile = NULL;
    hashtable->spaceUsed = 0;
    hashtable->spacePeak = 0;
    hashtable->spaceAllowed = space_allowed;
    hashtable->spaceUsedSkew = 0;
    hashtable->spaceAllowedSkew =
        hashtable->spaceAllowed * SKEW_HASH_MEM_PERCENT / 100;
    hashtable->chunks = NULL;
    hashtable->current_chunk = NULL;
    hashtable->parallel_state = state->parallel_state;
    hashtable->area = state->ps.state->es_query_dsa;
    hashtable->batches = NULL;
 
#ifdef HJDEBUG
    printf("Hashjoin %p: initial nbatch = %d, nbuckets = %d\n",
           hashtable, nbatch, nbuckets);
#endif
 
    /*
     * Create temporary memory contexts in which to keep the hashtable working
     * storage.  See notes in executor/hashjoin.h.
     */
    hashtable->hashCxt = AllocSetContextCreate(CurrentMemoryContext,
                                               "HashTableContext",
                                               ALLOCSET_DEFAULT_SIZES);
 
    hashtable->batchCxt = AllocSetContextCreate(hashtable->hashCxt,
                                                "HashBatchContext",
                                                ALLOCSET_DEFAULT_SIZES);
 
    hashtable->spillCxt = AllocSetContextCreate(hashtable->hashCxt,
                                                "HashSpillContext",
                                                ALLOCSET_DEFAULT_SIZES);
 
    /* Allocate data that will live for the life of the hashjoin */
 
    oldcxt = MemoryContextSwitchTo(hashtable->hashCxt);
 
    /*
     * Get info about the hash functions to be used for each hash key. Also
     * remember whether the join operators are strict.
     */
    nkeys = list_length(hashOperators);
    hashtable->outer_hashfunctions = palloc_array(FmgrInfo, nkeys);
    hashtable->inner_hashfunctions = palloc_array(FmgrInfo, nkeys);
    hashtable->hashStrict = palloc_array(bool, nkeys);
    hashtable->collations = palloc_array(Oid, nkeys);
    i = 0;
    forboth(ho, hashOperators, hc, hashCollations)
    {
        Oid         hashop = lfirst_oid(ho);
        Oid         left_hashfn;
        Oid         right_hashfn;
 
        if (!get_op_hash_functions(hashop, &left_hashfn, &right_hashfn))
            elog(ERROR, "could not find hash function for hash operator %u",
                 hashop);
        fmgr_info(left_hashfn, &hashtable->outer_hashfunctions[i]);
        fmgr_info(right_hashfn, &hashtable->inner_hashfunctions[i]);
        hashtable->hashStrict[i] = op_strict(hashop);
        hashtable->collations[i] = lfirst_oid(hc);
        i++;
    }
 
    if (nbatch > 1 && hashtable->parallel_state == NULL)
    {
        MemoryContext oldctx;
 
        /*
         * allocate and initialize the file arrays in hashCxt (not needed for
         * parallel case which uses shared tuplestores instead of raw files)
         */
        oldctx = MemoryContextSwitchTo(hashtable->spillCxt);
 
        hashtable->innerBatchFile = palloc0_array(BufFile *, nbatch);
        hashtable->outerBatchFile = palloc0_array(BufFile *, nbatch);
 
        MemoryContextSwitchTo(oldctx);
 
        /* The files will not be opened until needed... */
        /* ... but make sure we have temp tablespaces established for them */
        PrepareTempTablespaces();
    }
 
    MemoryContextSwitchTo(oldcxt);
 
    if (hashtable->parallel_state)
    {
        ParallelHashJoinState *pstate = hashtable->parallel_state;
        Barrier    *build_barrier;
 
        /*
         * Attach to the build barrier.  The corresponding detach operation is
         * in ExecHashTableDetach.  Note that we won't attach to the
         * batch_barrier for batch 0 yet.  We'll attach later and start it out
         * in PHJ_BATCH_PROBE phase, because batch 0 is allocated up front and
         * then loaded while hashing (the standard hybrid hash join
         * algorithm), and we'll coordinate that using build_barrier.
         */
        build_barrier = &pstate->build_barrier;
        BarrierAttach(build_barrier);
 
        /*
         * So far we have no idea whether there are any other participants,
         * and if so, what phase they are working on.  The only thing we care
         * about at this point is whether someone has already created the
         * SharedHashJoinBatch objects and the hash table for batch 0.  One
         * backend will be elected to do that now if necessary.
         */
        if (BarrierPhase(build_barrier) == PHJ_BUILD_ELECT &&
            BarrierArriveAndWait(build_barrier, WAIT_EVENT_HASH_BUILD_ELECT))
        {
            pstate->nbatch = nbatch;
            pstate->space_allowed = space_allowed;
            pstate->growth = PHJ_GROWTH_OK;
 
            /* Set up the shared state for coordinating batches. */
            ExecParallelHashJoinSetUpBatches(hashtable, nbatch);
 
            /*
             * Allocate batch 0's hash table up front so we can load it
             * directly while hashing.
             */
            pstate->nbuckets = nbuckets;
            ExecParallelHashTableAlloc(hashtable, 0);
        }
 
        /*
         * The next Parallel Hash synchronization point is in
         * MultiExecParallelHash(), which will progress it all the way to
         * PHJ_BUILD_RUN.  The caller must not return control from this
         * executor node between now and then.
         */
    }
    else
    {
        /*
         * Prepare context for the first-scan space allocations; allocate the
         * hashbucket array therein, and set each bucket "empty".
         */
        MemoryContextSwitchTo(hashtable->batchCxt);
 
        hashtable->buckets.unshared = palloc0_array(HashJoinTuple, nbuckets);
 
        /*
         * Set up for skew optimization, if possible and there's a need for
         * more than one batch.  (In a one-batch join, there's no point in
         * it.)
         */
        if (nbatch > 1)
            ExecHashBuildSkewHash(hashtable, node, num_skew_mcvs);
 
        MemoryContextSwitchTo(oldcxt);
    }
 
    return hashtable;
}

References ALLOCSET_DEFAULT_SIZES, AllocSetContextCreate, HashJoinTableData::area, Assert(), BarrierArriveAndWait(), BarrierAttach(), BarrierPhase(), HashJoinTableData::batchCxt, HashJoinTableData::batches, HashJoinTableData::buckets, ParallelHashJoinState::build_barrier, HashJoinTableData::chunks, HashJoinTableData::collations, HashJoinTableData::curbatch, HashJoinTableData::current_chunk, CurrentMemoryContext, elog(), ERROR, ExecChooseHashTableSize(), ExecHashBuildSkewHash(), ExecParallelHashJoinSetUpBatches(), ExecParallelHashTableAlloc(), fmgr_info(), forboth, get_op_hash_functions(), HashJoinTableData::growEnabled, ParallelHashJoinState::growth, HashJoinTableData::hashCxt, HashJoinTableData::hashStrict, i, HashJoinTableData::inner_hashfunctions, HashJoinTableData::innerBatchFile, HashJoinTableData::keepNulls, lfirst_oid, list_length(), HashJoinTableData::log2_nbuckets, HashJoinTableData::log2_nbuckets_optimal, MemoryContextSwitchTo(), my_log2(), ParallelHashJoinState::nbatch, HashJoinTableData::nbatch, HashJoinTableData::nbatch_original, HashJoinTableData::nbatch_outstart, ParallelHashJoinState::nbuckets, HashJoinTableData::nbuckets, HashJoinTableData::nbuckets_optimal, HashJoinTableData::nbuckets_original, HashJoinTableData::nSkewBuckets, OidIsValid, op_strict(), HashJoinTableData::outer_hashfunctions, HashJoinTableData::outerBatchFile, outerPlan, palloc0_array, palloc_array, palloc_object, Plan::parallel_aware, HashJoinTableData::parallel_state, HashJoinTableData::partialTuples, PHJ_BUILD_ELECT, PHJ_GROWTH_OK, Hash::plan, Plan::plan_rows, Plan::plan_width, PrepareTempTablespaces(), printf, Hash::rows_total, SKEW_HASH_MEM_PERCENT, HashJoinTableData::skewBucket, HashJoinTableData::skewBucketLen, HashJoinTableData::skewBucketNums, HashJoinTableData::skewEnabled, Hash::skewTable, HashJoinTableData::skewTuples, ParallelHashJoinState::space_allowed, HashJoinTableData::spaceAllowed, HashJoinTableData::spaceAllowedSkew, HashJoinTableData::spacePeak, HashJoinTableData::spaceUsed, HashJoinTableData::spaceUsedSkew, HashJoinTableData::spillCxt, HashJoinTableData::totalTuples, HashJoinTableData::unshared, and WAIT_EVENT_HASH_BUILD_ELECT.

Referenced by ExecHashJoinImpl().

ExecHashTableDestroy()

void ExecHashTableDestroy

(

HashJoinTable

hashtable

)

Definition at line 889 of file nodeHash.c.

{
    int         i;
 
    /*
     * Make sure all the temp files are closed.  We skip batch 0, since it
     * can't have any temp files (and the arrays might not even exist if
     * nbatch is only 1).  Parallel hash joins don't use these files.
     */
    if (hashtable->innerBatchFile != NULL)
    {
        for (i = 1; i < hashtable->nbatch; i++)
        {
            if (hashtable->innerBatchFile[i])
                BufFileClose(hashtable->innerBatchFile[i]);
            if (hashtable->outerBatchFile[i])
                BufFileClose(hashtable->outerBatchFile[i]);
        }
    }
 
    /* Release working memory (batchCxt is a child, so it goes away too) */
    MemoryContextDelete(hashtable->hashCxt);
 
    /* And drop the control block */
    pfree(hashtable);
}

References BufFileClose(), HashJoinTableData::hashCxt, i, HashJoinTableData::innerBatchFile, MemoryContextDelete(), HashJoinTableData::nbatch, HashJoinTableData::outerBatchFile, and pfree().

Referenced by ExecEndHashJoin(), and ExecReScanHashJoin().

ExecHashTableDetach()

void ExecHashTableDetach

(

HashJoinTable

hashtable

)

Definition at line 3371 of file nodeHash.c.

{
    ParallelHashJoinState *pstate = hashtable->parallel_state;
 
    /*
     * If we're involved in a parallel query, we must either have gotten all
     * the way to PHJ_BUILD_RUN, or joined too late and be in PHJ_BUILD_FREE.
     */
    Assert(!pstate ||
           BarrierPhase(&pstate->build_barrier) >= PHJ_BUILD_RUN);
 
    if (pstate && BarrierPhase(&pstate->build_barrier) == PHJ_BUILD_RUN)
    {
        int         i;
 
        /* Make sure any temporary files are closed. */
        if (hashtable->batches)
        {
            for (i = 0; i < hashtable->nbatch; ++i)
            {
                sts_end_write(hashtable->batches[i].inner_tuples);
                sts_end_write(hashtable->batches[i].outer_tuples);
                sts_end_parallel_scan(hashtable->batches[i].inner_tuples);
                sts_end_parallel_scan(hashtable->batches[i].outer_tuples);
            }
        }
 
        /* If we're last to detach, clean up shared memory. */
        if (BarrierArriveAndDetach(&pstate->build_barrier))
        {
            /*
             * Late joining processes will see this state and give up
             * immediately.
             */
            Assert(BarrierPhase(&pstate->build_barrier) == PHJ_BUILD_FREE);
 
            if (DsaPointerIsValid(pstate->batches))
            {
                dsa_free(hashtable->area, pstate->batches);
                pstate->batches = InvalidDsaPointer;
            }
        }
    }
    hashtable->parallel_state = NULL;
}

References HashJoinTableData::area, Assert(), BarrierArriveAndDetach(), BarrierPhase(), ParallelHashJoinState::batches, HashJoinTableData::batches, ParallelHashJoinState::build_barrier, dsa_free(), DsaPointerIsValid, i, ParallelHashJoinBatchAccessor::inner_tuples, InvalidDsaPointer, HashJoinTableData::nbatch, ParallelHashJoinBatchAccessor::outer_tuples, HashJoinTableData::parallel_state, PHJ_BUILD_FREE, PHJ_BUILD_RUN, sts_end_parallel_scan(), and sts_end_write().

Referenced by ExecHashJoinReInitializeDSM(), and ExecShutdownHashJoin().

ExecHashTableDetachBatch()

void ExecHashTableDetachBatch

(

HashJoinTable

hashtable

)

Definition at line 3279 of file nodeHash.c.

{
    if (hashtable->parallel_state != NULL &&
        hashtable->curbatch >= 0)
    {
        int         curbatch = hashtable->curbatch;
        ParallelHashJoinBatch *batch = hashtable->batches[curbatch].shared;
        bool        attached = true;
 
        /* Make sure any temporary files are closed. */
        sts_end_parallel_scan(hashtable->batches[curbatch].inner_tuples);
        sts_end_parallel_scan(hashtable->batches[curbatch].outer_tuples);
 
        /* After attaching we always get at least to PHJ_BATCH_PROBE. */
        Assert(BarrierPhase(&batch->batch_barrier) == PHJ_BATCH_PROBE ||
               BarrierPhase(&batch->batch_barrier) == PHJ_BATCH_SCAN);
 
        /*
         * If we're abandoning the PHJ_BATCH_PROBE phase early without having
         * reached the end of it, it means the plan doesn't want any more
         * tuples, and it is happy to abandon any tuples buffered in this
         * process's subplans.  For correctness, we can't allow any process to
         * execute the PHJ_BATCH_SCAN phase, because we will never have the
         * complete set of match bits.  Therefore we skip emitting unmatched
         * tuples in all backends (if this is a full/right join), as if those
         * tuples were all due to be emitted by this process and it has
         * abandoned them too.
         */
        if (BarrierPhase(&batch->batch_barrier) == PHJ_BATCH_PROBE &&
            !hashtable->batches[curbatch].outer_eof)
        {
            /*
             * This flag may be written to by multiple backends during
             * PHJ_BATCH_PROBE phase, but will only be read in PHJ_BATCH_SCAN
             * phase so requires no extra locking.
             */
            batch->skip_unmatched = true;
        }
 
        /*
         * Even if we aren't doing a full/right outer join, we'll step through
         * the PHJ_BATCH_SCAN phase just to maintain the invariant that
         * freeing happens in PHJ_BATCH_FREE, but that'll be wait-free.
         */
        if (BarrierPhase(&batch->batch_barrier) == PHJ_BATCH_PROBE)
            attached = BarrierArriveAndDetachExceptLast(&batch->batch_barrier);
        if (attached && BarrierArriveAndDetach(&batch->batch_barrier))
        {
            /*
             * We are not longer attached to the batch barrier, but we're the
             * process that was chosen to free resources and it's safe to
             * assert the current phase.  The ParallelHashJoinBatch can't go
             * away underneath us while we are attached to the build barrier,
             * making this access safe.
             */
            Assert(BarrierPhase(&batch->batch_barrier) == PHJ_BATCH_FREE);
 
            /* Free shared chunks and buckets. */
            while (DsaPointerIsValid(batch->chunks))
            {
                HashMemoryChunk chunk =
                    dsa_get_address(hashtable->area, batch->chunks);
                dsa_pointer next = chunk->next.shared;
 
                dsa_free(hashtable->area, batch->chunks);
                batch->chunks = next;
            }
            if (DsaPointerIsValid(batch->buckets))
            {
                dsa_free(hashtable->area, batch->buckets);
                batch->buckets = InvalidDsaPointer;
            }
        }
 
        /*
         * Track the largest batch we've been attached to.  Though each
         * backend might see a different subset of batches, explain.c will
         * scan the results from all backends to find the largest value.
         */
        hashtable->spacePeak =
            Max(hashtable->spacePeak,
                batch->size + sizeof(dsa_pointer_atomic) * hashtable->nbuckets);
 
        /* Remember that we are not attached to a batch. */
        hashtable->curbatch = -1;
    }
}

References HashJoinTableData::area, Assert(), BarrierArriveAndDetach(), BarrierArriveAndDetachExceptLast(), BarrierPhase(), ParallelHashJoinBatch::batch_barrier, HashJoinTableData::batches, ParallelHashJoinBatch::buckets, ParallelHashJoinBatch::chunks, HashJoinTableData::curbatch, dsa_free(), dsa_get_address(), DsaPointerIsValid, ParallelHashJoinBatchAccessor::inner_tuples, InvalidDsaPointer, Max, HashJoinTableData::nbuckets, next, HashMemoryChunkData::next, ParallelHashJoinBatchAccessor::outer_eof, ParallelHashJoinBatchAccessor::outer_tuples, HashJoinTableData::parallel_state, PHJ_BATCH_FREE, PHJ_BATCH_PROBE, PHJ_BATCH_SCAN, HashMemoryChunkData::shared, ParallelHashJoinBatchAccessor::shared, ParallelHashJoinBatch::size, ParallelHashJoinBatch::skip_unmatched, HashJoinTableData::spacePeak, and sts_end_parallel_scan().

Referenced by ExecHashJoinReInitializeDSM(), ExecParallelHashJoinNewBatch(), ExecParallelPrepHashTableForUnmatched(), and ExecShutdownHashJoin().

ExecHashTableInsert()

void ExecHashTableInsert	(	HashJoinTable	hashtable,
		TupleTableSlot *	slot,
		uint32	hashvalue
	)

Definition at line 1621 of file nodeHash.c.

{
    bool        shouldFree;
    MinimalTuple tuple = ExecFetchSlotMinimalTuple(slot, &shouldFree);
    int         bucketno;
    int         batchno;
 
    ExecHashGetBucketAndBatch(hashtable, hashvalue,
                              &bucketno, &batchno);
 
    /*
     * decide whether to put the tuple in the hash table or a temp file
     */
    if (batchno == hashtable->curbatch)
    {
        /*
         * put the tuple in hash table
         */
        HashJoinTuple hashTuple;
        int         hashTupleSize;
        double      ntuples = (hashtable->totalTuples - hashtable->skewTuples);
 
        /* Create the HashJoinTuple */
        hashTupleSize = HJTUPLE_OVERHEAD + tuple->t_len;
        hashTuple = (HashJoinTuple) dense_alloc(hashtable, hashTupleSize);
 
        hashTuple->hashvalue = hashvalue;
        memcpy(HJTUPLE_MINTUPLE(hashTuple), tuple, tuple->t_len);
 
        /*
         * We always reset the tuple-matched flag on insertion.  This is okay
         * even when reloading a tuple from a batch file, since the tuple
         * could not possibly have been matched to an outer tuple before it
         * went into the batch file.
         */
        HeapTupleHeaderClearMatch(HJTUPLE_MINTUPLE(hashTuple));
 
        /* Push it onto the front of the bucket's list */
        hashTuple->next.unshared = hashtable->buckets.unshared[bucketno];
        hashtable->buckets.unshared[bucketno] = hashTuple;
 
        /*
         * Increase the (optimal) number of buckets if we just exceeded the
         * NTUP_PER_BUCKET threshold, but only when there's still a single
         * batch.
         */
        if (hashtable->nbatch == 1 &&
            ntuples > (hashtable->nbuckets_optimal * NTUP_PER_BUCKET))
        {
            /* Guard against integer overflow and alloc size overflow */
            if (hashtable->nbuckets_optimal <= INT_MAX / 2 &&
                hashtable->nbuckets_optimal * 2 <= MaxAllocSize / sizeof(HashJoinTuple))
            {
                hashtable->nbuckets_optimal *= 2;
                hashtable->log2_nbuckets_optimal += 1;
            }
        }
 
        /* Account for space used, and back off if we've used too much */
        hashtable->spaceUsed += hashTupleSize;
        if (hashtable->spaceUsed > hashtable->spacePeak)
            hashtable->spacePeak = hashtable->spaceUsed;
        if (hashtable->spaceUsed +
            hashtable->nbuckets_optimal * sizeof(HashJoinTuple)
            > hashtable->spaceAllowed)
            ExecHashIncreaseNumBatches(hashtable);
    }
    else
    {
        /*
         * put the tuple into a temp file for later batches
         */
        Assert(batchno > hashtable->curbatch);
        ExecHashJoinSaveTuple(tuple,
                              hashvalue,
                              &hashtable->innerBatchFile[batchno],
                              hashtable);
    }
 
    if (shouldFree)
        heap_free_minimal_tuple(tuple);
}

References Assert(), HashJoinTableData::buckets, HashJoinTableData::curbatch, dense_alloc(), ExecFetchSlotMinimalTuple(), ExecHashGetBucketAndBatch(), ExecHashIncreaseNumBatches(), ExecHashJoinSaveTuple(), HashJoinTupleData::hashvalue, heap_free_minimal_tuple(), HeapTupleHeaderClearMatch, HJTUPLE_MINTUPLE, HJTUPLE_OVERHEAD, HashJoinTableData::innerBatchFile, HashJoinTableData::log2_nbuckets_optimal, MaxAllocSize, HashJoinTableData::nbatch, HashJoinTableData::nbuckets_optimal, HashJoinTupleData::next, NTUP_PER_BUCKET, HashJoinTableData::skewTuples, HashJoinTableData::spaceAllowed, HashJoinTableData::spacePeak, HashJoinTableData::spaceUsed, MinimalTupleData::t_len, HashJoinTableData::totalTuples, HashJoinTupleData::unshared, and HashJoinTableData::unshared.

Referenced by ExecHashJoinNewBatch(), and MultiExecPrivateHash().

ExecHashTableReset()

void ExecHashTableReset

(

HashJoinTable

hashtable

)

Definition at line 2296 of file nodeHash.c.

{
    MemoryContext oldcxt;
    int         nbuckets = hashtable->nbuckets;
 
    /*
     * Release all the hash buckets and tuples acquired in the prior pass, and
     * reinitialize the context for a new pass.
     */
    MemoryContextReset(hashtable->batchCxt);
    oldcxt = MemoryContextSwitchTo(hashtable->batchCxt);
 
    /* Reallocate and reinitialize the hash bucket headers. */
    hashtable->buckets.unshared = palloc0_array(HashJoinTuple, nbuckets);
 
    hashtable->spaceUsed = 0;
 
    MemoryContextSwitchTo(oldcxt);
 
    /* Forget the chunks (the memory was freed by the context reset above). */
    hashtable->chunks = NULL;
}

References HashJoinTableData::batchCxt, HashJoinTableData::buckets, HashJoinTableData::chunks, MemoryContextReset(), MemoryContextSwitchTo(), HashJoinTableData::nbuckets, palloc0_array, HashJoinTableData::spaceUsed, and HashJoinTableData::unshared.

Referenced by ExecHashJoinNewBatch().

ExecHashTableResetMatchFlags()

void ExecHashTableResetMatchFlags

(

HashJoinTable

hashtable

)

Definition at line 2324 of file nodeHash.c.

{
    HashJoinTuple tuple;
    int         i;
 
    /* Reset all flags in the main table ... */
    for (i = 0; i < hashtable->nbuckets; i++)
    {
        for (tuple = hashtable->buckets.unshared[i]; tuple != NULL;
             tuple = tuple->next.unshared)
            HeapTupleHeaderClearMatch(HJTUPLE_MINTUPLE(tuple));
    }
 
    /* ... and the same for the skew buckets, if any */
    for (i = 0; i < hashtable->nSkewBuckets; i++)
    {
        int         j = hashtable->skewBucketNums[i];
        HashSkewBucket *skewBucket = hashtable->skewBucket[j];
 
        for (tuple = skewBucket->tuples; tuple != NULL; tuple = tuple->next.unshared)
            HeapTupleHeaderClearMatch(HJTUPLE_MINTUPLE(tuple));
    }
}

References HashJoinTableData::buckets, HeapTupleHeaderClearMatch, HJTUPLE_MINTUPLE, i, j, HashJoinTableData::nbuckets, HashJoinTupleData::next, HashJoinTableData::nSkewBuckets, HashJoinTableData::skewBucket, HashJoinTableData::skewBucketNums, HashSkewBucket::tuples, HashJoinTupleData::unshared, and HashJoinTableData::unshared.

Referenced by ExecReScanHashJoin().

ExecInitHash()

HashState* ExecInitHash	(	Hash *	node,
		EState *	estate,
		int	eflags
	)

Definition at line 361 of file nodeHash.c.

{
    HashState  *hashstate;
 
    /* check for unsupported flags */
    Assert(!(eflags & (EXEC_FLAG_BACKWARD | EXEC_FLAG_MARK)));
 
    /*
     * create state structure
     */
    hashstate = makeNode(HashState);
    hashstate->ps.plan = (Plan *) node;
    hashstate->ps.state = estate;
    hashstate->ps.ExecProcNode = ExecHash;
    hashstate->hashtable = NULL;
    hashstate->hashkeys = NIL;  /* will be set by parent HashJoin */
 
    /*
     * Miscellaneous initialization
     *
     * create expression context for node
     */
    ExecAssignExprContext(estate, &hashstate->ps);
 
    /*
     * initialize child nodes
     */
    outerPlanState(hashstate) = ExecInitNode(outerPlan(node), estate, eflags);
 
    /*
     * initialize our result slot and type. No need to build projection
     * because this node doesn't do projections.
     */
    ExecInitResultTupleSlotTL(&hashstate->ps, &TTSOpsMinimalTuple);
    hashstate->ps.ps_ProjInfo = NULL;
 
    /*
     * initialize child expressions
     */
    Assert(node->plan.qual == NIL);
    hashstate->hashkeys =
        ExecInitExprList(node->hashkeys, (PlanState *) hashstate);
 
    return hashstate;
}

References Assert(), EXEC_FLAG_BACKWARD, EXEC_FLAG_MARK, ExecAssignExprContext(), ExecHash(), ExecInitExprList(), ExecInitNode(), ExecInitResultTupleSlotTL(), PlanState::ExecProcNode, HashState::hashkeys, Hash::hashkeys, HashState::hashtable, makeNode, NIL, outerPlan, outerPlanState, PlanState::plan, Hash::plan, HashState::ps, PlanState::ps_ProjInfo, Plan::qual, PlanState::state, and TTSOpsMinimalTuple.

Referenced by ExecInitNode().

ExecParallelHashCloseBatchAccessors()

static void ExecParallelHashCloseBatchAccessors ( HashJoinTable  hashtable )

static

Definition at line 3174 of file nodeHash.c.

{
    int         i;
 
    for (i = 0; i < hashtable->nbatch; ++i)
    {
        /* Make sure no files are left open. */
        sts_end_write(hashtable->batches[i].inner_tuples);
        sts_end_write(hashtable->batches[i].outer_tuples);
        sts_end_parallel_scan(hashtable->batches[i].inner_tuples);
        sts_end_parallel_scan(hashtable->batches[i].outer_tuples);
    }
    pfree(hashtable->batches);
    hashtable->batches = NULL;
}

References HashJoinTableData::batches, i, ParallelHashJoinBatchAccessor::inner_tuples, HashJoinTableData::nbatch, ParallelHashJoinBatchAccessor::outer_tuples, pfree(), sts_end_parallel_scan(), and sts_end_write().

Referenced by ExecParallelHashEnsureBatchAccessors(), and ExecParallelHashIncreaseNumBatches().

ExecParallelHashEnsureBatchAccessors()

static void ExecParallelHashEnsureBatchAccessors ( HashJoinTable  hashtable )

static

Definition at line 3195 of file nodeHash.c.

{
    ParallelHashJoinState *pstate = hashtable->parallel_state;
    ParallelHashJoinBatch *batches;
    MemoryContext oldcxt;
    int         i;
 
    if (hashtable->batches != NULL)
    {
        if (hashtable->nbatch == pstate->nbatch)
            return;
        ExecParallelHashCloseBatchAccessors(hashtable);
    }
 
    /*
     * We should never see a state where the batch-tracking array is freed,
     * because we should have given up sooner if we join when the build
     * barrier has reached the PHJ_BUILD_FREE phase.
     */
    Assert(DsaPointerIsValid(pstate->batches));
 
    /*
     * Use hash join spill memory context to allocate accessors, including
     * buffers for the temporary files.
     */
    oldcxt = MemoryContextSwitchTo(hashtable->spillCxt);
 
    /* Allocate this backend's accessor array. */
    hashtable->nbatch = pstate->nbatch;
    hashtable->batches =
        palloc0_array(ParallelHashJoinBatchAccessor, hashtable->nbatch);
 
    /* Find the base of the pseudo-array of ParallelHashJoinBatch objects. */
    batches = (ParallelHashJoinBatch *)
        dsa_get_address(hashtable->area, pstate->batches);
 
    /* Set up the accessor array and attach to the tuplestores. */
    for (i = 0; i < hashtable->nbatch; ++i)
    {
        ParallelHashJoinBatchAccessor *accessor = &hashtable->batches[i];
        ParallelHashJoinBatch *shared = NthParallelHashJoinBatch(batches, i);
 
        accessor->shared = shared;
        accessor->preallocated = 0;
        accessor->done = false;
        accessor->outer_eof = false;
        accessor->inner_tuples =
            sts_attach(ParallelHashJoinBatchInner(shared),
                       ParallelWorkerNumber + 1,
                       &pstate->fileset);
        accessor->outer_tuples =
            sts_attach(ParallelHashJoinBatchOuter(shared,
                                                  pstate->nparticipants),
                       ParallelWorkerNumber + 1,
                       &pstate->fileset);
    }
 
    MemoryContextSwitchTo(oldcxt);
}

References HashJoinTableData::area, Assert(), ParallelHashJoinState::batches, HashJoinTableData::batches, ParallelHashJoinBatchAccessor::done, dsa_get_address(), DsaPointerIsValid, ExecParallelHashCloseBatchAccessors(), ParallelHashJoinState::fileset, i, ParallelHashJoinBatchAccessor::inner_tuples, MemoryContextSwitchTo(), ParallelHashJoinState::nbatch, HashJoinTableData::nbatch, ParallelHashJoinState::nparticipants, NthParallelHashJoinBatch, ParallelHashJoinBatchAccessor::outer_eof, ParallelHashJoinBatchAccessor::outer_tuples, palloc0_array, HashJoinTableData::parallel_state, ParallelHashJoinBatchInner, ParallelHashJoinBatchOuter, ParallelWorkerNumber, ParallelHashJoinBatchAccessor::preallocated, ParallelHashJoinBatchAccessor::shared, HashJoinTableData::spillCxt, and sts_attach().

Referenced by ExecParallelHashIncreaseNumBatches(), ExecParallelHashIncreaseNumBuckets(), and MultiExecParallelHash().

ExecParallelHashFirstTuple()

static HashJoinTuple ExecParallelHashFirstTuple ( HashJoinTable  hashtable, int  bucketno  )

inlinestatic

Definition at line 3421 of file nodeHash.c.

{
    HashJoinTuple tuple;
    dsa_pointer p;
 
    Assert(hashtable->parallel_state);
    p = dsa_pointer_atomic_read(&hashtable->buckets.shared[bucketno]);
    tuple = (HashJoinTuple) dsa_get_address(hashtable->area, p);
 
    return tuple;
}

References HashJoinTableData::area, Assert(), HashJoinTableData::buckets, dsa_get_address(), dsa_pointer_atomic_read, HashJoinTableData::parallel_state, and HashJoinTableData::shared.

Referenced by ExecParallelScanHashBucket(), and ExecParallelScanHashTableForUnmatched().

ExecParallelHashIncreaseNumBatches()

static void ExecParallelHashIncreaseNumBatches ( HashJoinTable  hashtable )

static

Definition at line 1086 of file nodeHash.c.

{
    ParallelHashJoinState *pstate = hashtable->parallel_state;
 
    Assert(BarrierPhase(&pstate->build_barrier) == PHJ_BUILD_HASH_INNER);
 
    /*
     * It's unlikely, but we need to be prepared for new participants to show
     * up while we're in the middle of this operation so we need to switch on
     * barrier phase here.
     */
    switch (PHJ_GROW_BATCHES_PHASE(BarrierPhase(&pstate->grow_batches_barrier)))
    {
        case PHJ_GROW_BATCHES_ELECT:
 
            /*
             * Elect one participant to prepare to grow the number of batches.
             * This involves reallocating or resetting the buckets of batch 0
             * in preparation for all participants to begin repartitioning the
             * tuples.
             */
            if (BarrierArriveAndWait(&pstate->grow_batches_barrier,
                                     WAIT_EVENT_HASH_GROW_BATCHES_ELECT))
            {
                dsa_pointer_atomic *buckets;
                ParallelHashJoinBatch *old_batch0;
                int         new_nbatch;
                int         i;
 
                /* Move the old batch out of the way. */
                old_batch0 = hashtable->batches[0].shared;
                pstate->old_batches = pstate->batches;
                pstate->old_nbatch = hashtable->nbatch;
                pstate->batches = InvalidDsaPointer;
 
                /* Free this backend's old accessors. */
                ExecParallelHashCloseBatchAccessors(hashtable);
 
                /* Figure out how many batches to use. */
                if (hashtable->nbatch == 1)
                {
                    /*
                     * We are going from single-batch to multi-batch.  We need
                     * to switch from one large combined memory budget to the
                     * regular hash_mem budget.
                     */
                    pstate->space_allowed = get_hash_memory_limit();
 
                    /*
                     * The combined hash_mem of all participants wasn't
                     * enough. Therefore one batch per participant would be
                     * approximately equivalent and would probably also be
                     * insufficient.  So try two batches per participant,
                     * rounded up to a power of two.
                     */
                    new_nbatch = pg_nextpower2_32(pstate->nparticipants * 2);
                }
                else
                {
                    /*
                     * We were already multi-batched.  Try doubling the number
                     * of batches.
                     */
                    new_nbatch = hashtable->nbatch * 2;
                }
 
                /* Allocate new larger generation of batches. */
                Assert(hashtable->nbatch == pstate->nbatch);
                ExecParallelHashJoinSetUpBatches(hashtable, new_nbatch);
                Assert(hashtable->nbatch == pstate->nbatch);
 
                /* Replace or recycle batch 0's bucket array. */
                if (pstate->old_nbatch == 1)
                {
                    double      dtuples;
                    double      dbuckets;
                    int         new_nbuckets;
 
                    /*
                     * We probably also need a smaller bucket array.  How many
                     * tuples do we expect per batch, assuming we have only
                     * half of them so far?  Normally we don't need to change
                     * the bucket array's size, because the size of each batch
                     * stays the same as we add more batches, but in this
                     * special case we move from a large batch to many smaller
                     * batches and it would be wasteful to keep the large
                     * array.
                     */
                    dtuples = (old_batch0->ntuples * 2.0) / new_nbatch;
                    dbuckets = ceil(dtuples / NTUP_PER_BUCKET);
                    dbuckets = Min(dbuckets,
                                   MaxAllocSize / sizeof(dsa_pointer_atomic));
                    new_nbuckets = (int) dbuckets;
                    new_nbuckets = Max(new_nbuckets, 1024);
                    new_nbuckets = pg_nextpower2_32(new_nbuckets);
                    dsa_free(hashtable->area, old_batch0->buckets);
                    hashtable->batches[0].shared->buckets =
                        dsa_allocate(hashtable->area,
                                     sizeof(dsa_pointer_atomic) * new_nbuckets);
                    buckets = (dsa_pointer_atomic *)
                        dsa_get_address(hashtable->area,
                                        hashtable->batches[0].shared->buckets);
                    for (i = 0; i < new_nbuckets; ++i)
                        dsa_pointer_atomic_init(&buckets[i], InvalidDsaPointer);
                    pstate->nbuckets = new_nbuckets;
                }
                else
                {
                    /* Recycle the existing bucket array. */
                    hashtable->batches[0].shared->buckets = old_batch0->buckets;
                    buckets = (dsa_pointer_atomic *)
                        dsa_get_address(hashtable->area, old_batch0->buckets);
                    for (i = 0; i < hashtable->nbuckets; ++i)
                        dsa_pointer_atomic_write(&buckets[i], InvalidDsaPointer);
                }
 
                /* Move all chunks to the work queue for parallel processing. */
                pstate->chunk_work_queue = old_batch0->chunks;
 
                /* Disable further growth temporarily while we're growing. */
                pstate->growth = PHJ_GROWTH_DISABLED;
            }
            else
            {
                /* All other participants just flush their tuples to disk. */
                ExecParallelHashCloseBatchAccessors(hashtable);
            }
            /* Fall through. */
 
        case PHJ_GROW_BATCHES_REALLOCATE:
            /* Wait for the above to be finished. */
            BarrierArriveAndWait(&pstate->grow_batches_barrier,
                                 WAIT_EVENT_HASH_GROW_BATCHES_REALLOCATE);
            /* Fall through. */
 
        case PHJ_GROW_BATCHES_REPARTITION:
            /* Make sure that we have the current dimensions and buckets. */
            ExecParallelHashEnsureBatchAccessors(hashtable);
            ExecParallelHashTableSetCurrentBatch(hashtable, 0);
            /* Then partition, flush counters. */
            ExecParallelHashRepartitionFirst(hashtable);
            ExecParallelHashRepartitionRest(hashtable);
            ExecParallelHashMergeCounters(hashtable);
            /* Wait for the above to be finished. */
            BarrierArriveAndWait(&pstate->grow_batches_barrier,
                                 WAIT_EVENT_HASH_GROW_BATCHES_REPARTITION);
            /* Fall through. */
 
        case PHJ_GROW_BATCHES_DECIDE:
 
            /*
             * Elect one participant to clean up and decide whether further
             * repartitioning is needed, or should be disabled because it's
             * not helping.
             */
            if (BarrierArriveAndWait(&pstate->grow_batches_barrier,
                                     WAIT_EVENT_HASH_GROW_BATCHES_DECIDE))
            {
                bool        space_exhausted = false;
                bool        extreme_skew_detected = false;
 
                /* Make sure that we have the current dimensions and buckets. */
                ExecParallelHashEnsureBatchAccessors(hashtable);
                ExecParallelHashTableSetCurrentBatch(hashtable, 0);
 
                /* Are any of the new generation of batches exhausted? */
                for (int i = 0; i < hashtable->nbatch; ++i)
                {
                    ParallelHashJoinBatch *batch = hashtable->batches[i].shared;
 
                    if (batch->space_exhausted ||
                        batch->estimated_size > pstate->space_allowed)
                    {
                        int         parent;
 
                        space_exhausted = true;
 
                        /*
                         * Did this batch receive ALL of the tuples from its
                         * parent batch?  That would indicate that further
                         * repartitioning isn't going to help (the hash values
                         * are probably all the same).
                         */
                        parent = i % pstate->old_nbatch;
                        if (batch->ntuples == hashtable->batches[parent].shared->old_ntuples)
                            extreme_skew_detected = true;
                    }
                }
 
                /* Don't keep growing if it's not helping or we'd overflow. */
                if (extreme_skew_detected || hashtable->nbatch >= INT_MAX / 2)
                    pstate->growth = PHJ_GROWTH_DISABLED;
                else if (space_exhausted)
                    pstate->growth = PHJ_GROWTH_NEED_MORE_BATCHES;
                else
                    pstate->growth = PHJ_GROWTH_OK;
 
                /* Free the old batches in shared memory. */
                dsa_free(hashtable->area, pstate->old_batches);
                pstate->old_batches = InvalidDsaPointer;
            }
            /* Fall through. */
 
        case PHJ_GROW_BATCHES_FINISH:
            /* Wait for the above to complete. */
            BarrierArriveAndWait(&pstate->grow_batches_barrier,
                                 WAIT_EVENT_HASH_GROW_BATCHES_FINISH);
    }
}

References HashJoinTableData::area, Assert(), BarrierArriveAndWait(), BarrierPhase(), ParallelHashJoinState::batches, HashJoinTableData::batches, ParallelHashJoinBatch::buckets, ParallelHashJoinState::build_barrier, ParallelHashJoinState::chunk_work_queue, ParallelHashJoinBatch::chunks, dsa_allocate, dsa_free(), dsa_get_address(), dsa_pointer_atomic_init, dsa_pointer_atomic_write, ParallelHashJoinBatch::estimated_size, ExecParallelHashCloseBatchAccessors(), ExecParallelHashEnsureBatchAccessors(), ExecParallelHashJoinSetUpBatches(), ExecParallelHashMergeCounters(), ExecParallelHashRepartitionFirst(), ExecParallelHashRepartitionRest(), ExecParallelHashTableSetCurrentBatch(), get_hash_memory_limit(), ParallelHashJoinState::grow_batches_barrier, ParallelHashJoinState::growth, i, InvalidDsaPointer, Max, MaxAllocSize, Min, ParallelHashJoinState::nbatch, HashJoinTableData::nbatch, ParallelHashJoinState::nbuckets, HashJoinTableData::nbuckets, ParallelHashJoinState::nparticipants, NTUP_PER_BUCKET, ParallelHashJoinBatch::ntuples, ParallelHashJoinState::old_batches, ParallelHashJoinState::old_nbatch, ParallelHashJoinBatch::old_ntuples, HashJoinTableData::parallel_state, pg_nextpower2_32(), PHJ_BUILD_HASH_INNER, PHJ_GROW_BATCHES_DECIDE, PHJ_GROW_BATCHES_ELECT, PHJ_GROW_BATCHES_FINISH, PHJ_GROW_BATCHES_PHASE, PHJ_GROW_BATCHES_REALLOCATE, PHJ_GROW_BATCHES_REPARTITION, PHJ_GROWTH_DISABLED, PHJ_GROWTH_NEED_MORE_BATCHES, PHJ_GROWTH_OK, ParallelHashJoinBatchAccessor::shared, ParallelHashJoinState::space_allowed, ParallelHashJoinBatch::space_exhausted, WAIT_EVENT_HASH_GROW_BATCHES_DECIDE, WAIT_EVENT_HASH_GROW_BATCHES_ELECT, WAIT_EVENT_HASH_GROW_BATCHES_FINISH, WAIT_EVENT_HASH_GROW_BATCHES_REALLOCATE, and WAIT_EVENT_HASH_GROW_BATCHES_REPARTITION.

Referenced by ExecParallelHashTupleAlloc(), ExecParallelHashTuplePrealloc(), and MultiExecParallelHash().

ExecParallelHashIncreaseNumBuckets()

static void ExecParallelHashIncreaseNumBuckets ( HashJoinTable  hashtable )

static

Definition at line 1522 of file nodeHash.c.

{
    ParallelHashJoinState *pstate = hashtable->parallel_state;
    int         i;
    HashMemoryChunk chunk;
    dsa_pointer chunk_s;
 
    Assert(BarrierPhase(&pstate->build_barrier) == PHJ_BUILD_HASH_INNER);
 
    /*
     * It's unlikely, but we need to be prepared for new participants to show
     * up while we're in the middle of this operation so we need to switch on
     * barrier phase here.
     */
    switch (PHJ_GROW_BUCKETS_PHASE(BarrierPhase(&pstate->grow_buckets_barrier)))
    {
        case PHJ_GROW_BUCKETS_ELECT:
            /* Elect one participant to prepare to increase nbuckets. */
            if (BarrierArriveAndWait(&pstate->grow_buckets_barrier,
                                     WAIT_EVENT_HASH_GROW_BUCKETS_ELECT))
            {
                size_t      size;
                dsa_pointer_atomic *buckets;
 
                /* Double the size of the bucket array. */
                pstate->nbuckets *= 2;
                size = pstate->nbuckets * sizeof(dsa_pointer_atomic);
                hashtable->batches[0].shared->size += size / 2;
                dsa_free(hashtable->area, hashtable->batches[0].shared->buckets);
                hashtable->batches[0].shared->buckets =
                    dsa_allocate(hashtable->area, size);
                buckets = (dsa_pointer_atomic *)
                    dsa_get_address(hashtable->area,
                                    hashtable->batches[0].shared->buckets);
                for (i = 0; i < pstate->nbuckets; ++i)
                    dsa_pointer_atomic_init(&buckets[i], InvalidDsaPointer);
 
                /* Put the chunk list onto the work queue. */
                pstate->chunk_work_queue = hashtable->batches[0].shared->chunks;
 
                /* Clear the flag. */
                pstate->growth = PHJ_GROWTH_OK;
            }
            /* Fall through. */
 
        case PHJ_GROW_BUCKETS_REALLOCATE:
            /* Wait for the above to complete. */
            BarrierArriveAndWait(&pstate->grow_buckets_barrier,
                                 WAIT_EVENT_HASH_GROW_BUCKETS_REALLOCATE);
            /* Fall through. */
 
        case PHJ_GROW_BUCKETS_REINSERT:
            /* Reinsert all tuples into the hash table. */
            ExecParallelHashEnsureBatchAccessors(hashtable);
            ExecParallelHashTableSetCurrentBatch(hashtable, 0);
            while ((chunk = ExecParallelHashPopChunkQueue(hashtable, &chunk_s)))
            {
                size_t      idx = 0;
 
                while (idx < chunk->used)
                {
                    HashJoinTuple hashTuple = (HashJoinTuple) (HASH_CHUNK_DATA(chunk) + idx);
                    dsa_pointer shared = chunk_s + HASH_CHUNK_HEADER_SIZE + idx;
                    int         bucketno;
                    int         batchno;
 
                    ExecHashGetBucketAndBatch(hashtable, hashTuple->hashvalue,
                                              &bucketno, &batchno);
                    Assert(batchno == 0);
 
                    /* add the tuple to the proper bucket */
                    ExecParallelHashPushTuple(&hashtable->buckets.shared[bucketno],
                                              hashTuple, shared);
 
                    /* advance index past the tuple */
                    idx += MAXALIGN(HJTUPLE_OVERHEAD +
                                    HJTUPLE_MINTUPLE(hashTuple)->t_len);
                }
 
                /* allow this loop to be cancellable */
                CHECK_FOR_INTERRUPTS();
            }
            BarrierArriveAndWait(&pstate->grow_buckets_barrier,
                                 WAIT_EVENT_HASH_GROW_BUCKETS_REINSERT);
    }
}

References HashJoinTableData::area, Assert(), BarrierArriveAndWait(), BarrierPhase(), HashJoinTableData::batches, ParallelHashJoinBatch::buckets, HashJoinTableData::buckets, ParallelHashJoinState::build_barrier, CHECK_FOR_INTERRUPTS, ParallelHashJoinState::chunk_work_queue, ParallelHashJoinBatch::chunks, dsa_allocate, dsa_free(), dsa_get_address(), dsa_pointer_atomic_init, ExecHashGetBucketAndBatch(), ExecParallelHashEnsureBatchAccessors(), ExecParallelHashPopChunkQueue(), ExecParallelHashPushTuple(), ExecParallelHashTableSetCurrentBatch(), ParallelHashJoinState::grow_buckets_barrier, ParallelHashJoinState::growth, HASH_CHUNK_DATA, HASH_CHUNK_HEADER_SIZE, HashJoinTupleData::hashvalue, HJTUPLE_MINTUPLE, HJTUPLE_OVERHEAD, i, idx(), InvalidDsaPointer, MAXALIGN, ParallelHashJoinState::nbuckets, HashJoinTableData::parallel_state, PHJ_BUILD_HASH_INNER, PHJ_GROW_BUCKETS_ELECT, PHJ_GROW_BUCKETS_PHASE, PHJ_GROW_BUCKETS_REALLOCATE, PHJ_GROW_BUCKETS_REINSERT, PHJ_GROWTH_OK, ParallelHashJoinBatchAccessor::shared, HashJoinTableData::shared, ParallelHashJoinBatch::size, WAIT_EVENT_HASH_GROW_BUCKETS_ELECT, WAIT_EVENT_HASH_GROW_BUCKETS_REALLOCATE, and WAIT_EVENT_HASH_GROW_BUCKETS_REINSERT.

Referenced by ExecParallelHashTupleAlloc(), ExecParallelHashTuplePrealloc(), and MultiExecParallelHash().

ExecParallelHashJoinSetUpBatches()

static void ExecParallelHashJoinSetUpBatches ( HashJoinTable  hashtable, int  nbatch  )

static

Definition at line 3094 of file nodeHash.c.

{
    ParallelHashJoinState *pstate = hashtable->parallel_state;
    ParallelHashJoinBatch *batches;
    MemoryContext oldcxt;
    int         i;
 
    Assert(hashtable->batches == NULL);
 
    /* Allocate space. */
    pstate->batches =
        dsa_allocate0(hashtable->area,
                      EstimateParallelHashJoinBatch(hashtable) * nbatch);
    pstate->nbatch = nbatch;
    batches = dsa_get_address(hashtable->area, pstate->batches);
 
    /*
     * Use hash join spill memory context to allocate accessors, including
     * buffers for the temporary files.
     */
    oldcxt = MemoryContextSwitchTo(hashtable->spillCxt);
 
    /* Allocate this backend's accessor array. */
    hashtable->nbatch = nbatch;
    hashtable->batches =
        palloc0_array(ParallelHashJoinBatchAccessor, hashtable->nbatch);
 
    /* Set up the shared state, tuplestores and backend-local accessors. */
    for (i = 0; i < hashtable->nbatch; ++i)
    {
        ParallelHashJoinBatchAccessor *accessor = &hashtable->batches[i];
        ParallelHashJoinBatch *shared = NthParallelHashJoinBatch(batches, i);
        char        name[MAXPGPATH];
 
        /*
         * All members of shared were zero-initialized.  We just need to set
         * up the Barrier.
         */
        BarrierInit(&shared->batch_barrier, 0);
        if (i == 0)
        {
            /* Batch 0 doesn't need to be loaded. */
            BarrierAttach(&shared->batch_barrier);
            while (BarrierPhase(&shared->batch_barrier) < PHJ_BATCH_PROBE)
                BarrierArriveAndWait(&shared->batch_barrier, 0);
            BarrierDetach(&shared->batch_barrier);
        }
 
        /* Initialize accessor state.  All members were zero-initialized. */
        accessor->shared = shared;
 
        /* Initialize the shared tuplestores. */
        snprintf(name, sizeof(name), "i%dof%d", i, hashtable->nbatch);
        accessor->inner_tuples =
            sts_initialize(ParallelHashJoinBatchInner(shared),
                           pstate->nparticipants,
                           ParallelWorkerNumber + 1,
                           sizeof(uint32),
                           SHARED_TUPLESTORE_SINGLE_PASS,
                           &pstate->fileset,
                           name);
        snprintf(name, sizeof(name), "o%dof%d", i, hashtable->nbatch);
        accessor->outer_tuples =
            sts_initialize(ParallelHashJoinBatchOuter(shared,
                                                      pstate->nparticipants),
                           pstate->nparticipants,
                           ParallelWorkerNumber + 1,
                           sizeof(uint32),
                           SHARED_TUPLESTORE_SINGLE_PASS,
                           &pstate->fileset,
                           name);
    }
 
    MemoryContextSwitchTo(oldcxt);
}

References HashJoinTableData::area, Assert(), BarrierArriveAndWait(), BarrierAttach(), BarrierDetach(), BarrierInit(), BarrierPhase(), ParallelHashJoinBatch::batch_barrier, ParallelHashJoinState::batches, HashJoinTableData::batches, dsa_allocate0, dsa_get_address(), EstimateParallelHashJoinBatch, ParallelHashJoinState::fileset, i, ParallelHashJoinBatchAccessor::inner_tuples, MAXPGPATH, MemoryContextSwitchTo(), name, ParallelHashJoinState::nbatch, HashJoinTableData::nbatch, ParallelHashJoinState::nparticipants, NthParallelHashJoinBatch, ParallelHashJoinBatchAccessor::outer_tuples, palloc0_array, HashJoinTableData::parallel_state, ParallelHashJoinBatchInner, ParallelHashJoinBatchOuter, ParallelWorkerNumber, PHJ_BATCH_PROBE, ParallelHashJoinBatchAccessor::shared, SHARED_TUPLESTORE_SINGLE_PASS, snprintf, HashJoinTableData::spillCxt, and sts_initialize().

Referenced by ExecHashTableCreate(), and ExecParallelHashIncreaseNumBatches().

ExecParallelHashMergeCounters()

static void ExecParallelHashMergeCounters ( HashJoinTable  hashtable )

static

Definition at line 1429 of file nodeHash.c.

{
    ParallelHashJoinState *pstate = hashtable->parallel_state;
    int         i;
 
    LWLockAcquire(&pstate->lock, LW_EXCLUSIVE);
    pstate->total_tuples = 0;
    for (i = 0; i < hashtable->nbatch; ++i)
    {
        ParallelHashJoinBatchAccessor *batch = &hashtable->batches[i];
 
        batch->shared->size += batch->size;
        batch->shared->estimated_size += batch->estimated_size;
        batch->shared->ntuples += batch->ntuples;
        batch->shared->old_ntuples += batch->old_ntuples;
        batch->size = 0;
        batch->estimated_size = 0;
        batch->ntuples = 0;
        batch->old_ntuples = 0;
        pstate->total_tuples += batch->shared->ntuples;
    }
    LWLockRelease(&pstate->lock);
}

References HashJoinTableData::batches, ParallelHashJoinBatch::estimated_size, ParallelHashJoinBatchAccessor::estimated_size, i, ParallelHashJoinState::lock, LW_EXCLUSIVE, LWLockAcquire(), LWLockRelease(), HashJoinTableData::nbatch, ParallelHashJoinBatch::ntuples, ParallelHashJoinBatchAccessor::ntuples, ParallelHashJoinBatch::old_ntuples, ParallelHashJoinBatchAccessor::old_ntuples, HashJoinTableData::parallel_state, ParallelHashJoinBatchAccessor::shared, ParallelHashJoinBatch::size, ParallelHashJoinBatchAccessor::size, and ParallelHashJoinState::total_tuples.

Referenced by ExecParallelHashIncreaseNumBatches(), and MultiExecParallelHash().

ExecParallelHashNextTuple()

static HashJoinTuple ExecParallelHashNextTuple ( HashJoinTable  hashtable, HashJoinTuple  tuple  )

inlinestatic

Definition at line 3437 of file nodeHash.c.

{
    HashJoinTuple next;
 
    Assert(hashtable->parallel_state);
    next = (HashJoinTuple) dsa_get_address(hashtable->area, tuple->next.shared);
 
    return next;
}

References HashJoinTableData::area, Assert(), dsa_get_address(), next, HashJoinTupleData::next, HashJoinTableData::parallel_state, and HashJoinTupleData::shared.

Referenced by ExecParallelScanHashBucket(), and ExecParallelScanHashTableForUnmatched().

ExecParallelHashPopChunkQueue()

static HashMemoryChunk ExecParallelHashPopChunkQueue ( HashJoinTable  hashtable, dsa_pointer *  shared  )

static

Definition at line 3490 of file nodeHash.c.

{
    ParallelHashJoinState *pstate = hashtable->parallel_state;
    HashMemoryChunk chunk;
 
    LWLockAcquire(&pstate->lock, LW_EXCLUSIVE);
    if (DsaPointerIsValid(pstate->chunk_work_queue))
    {
        *shared = pstate->chunk_work_queue;
        chunk = (HashMemoryChunk)
            dsa_get_address(hashtable->area, *shared);
        pstate->chunk_work_queue = chunk->next.shared;
    }
    else
        chunk = NULL;
    LWLockRelease(&pstate->lock);
 
    return chunk;
}

References HashJoinTableData::area, ParallelHashJoinState::chunk_work_queue, dsa_get_address(), DsaPointerIsValid, ParallelHashJoinState::lock, LW_EXCLUSIVE, LWLockAcquire(), LWLockRelease(), HashMemoryChunkData::next, HashJoinTableData::parallel_state, and HashMemoryChunkData::shared.

Referenced by ExecParallelHashIncreaseNumBuckets(), and ExecParallelHashRepartitionFirst().

ExecParallelHashPushTuple()

static void ExecParallelHashPushTuple ( dsa_pointer_atomic *  head, HashJoinTuple  tuple, dsa_pointer  tuple_shared  )

inlinestatic

Definition at line 3451 of file nodeHash.c.

{
    for (;;)
    {
        tuple->next.shared = dsa_pointer_atomic_read(head);
        if (dsa_pointer_atomic_compare_exchange(head,
                                                &tuple->next.shared,
                                                tuple_shared))
            break;
    }
}

References dsa_pointer_atomic_compare_exchange, dsa_pointer_atomic_read, HashJoinTupleData::next, and HashJoinTupleData::shared.

Referenced by ExecParallelHashIncreaseNumBuckets(), ExecParallelHashRepartitionFirst(), ExecParallelHashTableInsert(), and ExecParallelHashTableInsertCurrentBatch().

ExecParallelHashRepartitionFirst()

static void ExecParallelHashRepartitionFirst ( HashJoinTable  hashtable )

static

Definition at line 1302 of file nodeHash.c.

{
    dsa_pointer chunk_shared;
    HashMemoryChunk chunk;
 
    Assert(hashtable->nbatch == hashtable->parallel_state->nbatch);
 
    while ((chunk = ExecParallelHashPopChunkQueue(hashtable, &chunk_shared)))
    {
        size_t      idx = 0;
 
        /* Repartition all tuples in this chunk. */
        while (idx < chunk->used)
        {
            HashJoinTuple hashTuple = (HashJoinTuple) (HASH_CHUNK_DATA(chunk) + idx);
            MinimalTuple tuple = HJTUPLE_MINTUPLE(hashTuple);
            HashJoinTuple copyTuple;
            dsa_pointer shared;
            int         bucketno;
            int         batchno;
 
            ExecHashGetBucketAndBatch(hashtable, hashTuple->hashvalue,
                                      &bucketno, &batchno);
 
            Assert(batchno < hashtable->nbatch);
            if (batchno == 0)
            {
                /* It still belongs in batch 0.  Copy to a new chunk. */
                copyTuple =
                    ExecParallelHashTupleAlloc(hashtable,
                                               HJTUPLE_OVERHEAD + tuple->t_len,
                                               &shared);
                copyTuple->hashvalue = hashTuple->hashvalue;
                memcpy(HJTUPLE_MINTUPLE(copyTuple), tuple, tuple->t_len);
                ExecParallelHashPushTuple(&hashtable->buckets.shared[bucketno],
                                          copyTuple, shared);
            }
            else
            {
                size_t      tuple_size =
                    MAXALIGN(HJTUPLE_OVERHEAD + tuple->t_len);
 
                /* It belongs in a later batch. */
                hashtable->batches[batchno].estimated_size += tuple_size;
                sts_puttuple(hashtable->batches[batchno].inner_tuples,
                             &hashTuple->hashvalue, tuple);
            }
 
            /* Count this tuple. */
            ++hashtable->batches[0].old_ntuples;
            ++hashtable->batches[batchno].ntuples;
 
            idx += MAXALIGN(HJTUPLE_OVERHEAD +
                            HJTUPLE_MINTUPLE(hashTuple)->t_len);
        }
 
        /* Free this chunk. */
        dsa_free(hashtable->area, chunk_shared);
 
        CHECK_FOR_INTERRUPTS();
    }
}

References HashJoinTableData::area, Assert(), HashJoinTableData::batches, HashJoinTableData::buckets, CHECK_FOR_INTERRUPTS, dsa_free(), ParallelHashJoinBatchAccessor::estimated_size, ExecHashGetBucketAndBatch(), ExecParallelHashPopChunkQueue(), ExecParallelHashPushTuple(), ExecParallelHashTupleAlloc(), HASH_CHUNK_DATA, HashJoinTupleData::hashvalue, HJTUPLE_MINTUPLE, HJTUPLE_OVERHEAD, idx(), ParallelHashJoinBatchAccessor::inner_tuples, MAXALIGN, ParallelHashJoinState::nbatch, HashJoinTableData::nbatch, ParallelHashJoinBatchAccessor::ntuples, ParallelHashJoinBatchAccessor::old_ntuples, HashJoinTableData::parallel_state, HashJoinTableData::shared, sts_puttuple(), and MinimalTupleData::t_len.

Referenced by ExecParallelHashIncreaseNumBatches().

ExecParallelHashRepartitionRest()

static void ExecParallelHashRepartitionRest ( HashJoinTable  hashtable )

static

Definition at line 1369 of file nodeHash.c.

{
    ParallelHashJoinState *pstate = hashtable->parallel_state;
    int         old_nbatch = pstate->old_nbatch;
    SharedTuplestoreAccessor **old_inner_tuples;
    ParallelHashJoinBatch *old_batches;
    int         i;
 
    /* Get our hands on the previous generation of batches. */
    old_batches = (ParallelHashJoinBatch *)
        dsa_get_address(hashtable->area, pstate->old_batches);
    old_inner_tuples = palloc0_array(SharedTuplestoreAccessor *, old_nbatch);
    for (i = 1; i < old_nbatch; ++i)
    {
        ParallelHashJoinBatch *shared =
            NthParallelHashJoinBatch(old_batches, i);
 
        old_inner_tuples[i] = sts_attach(ParallelHashJoinBatchInner(shared),
                                         ParallelWorkerNumber + 1,
                                         &pstate->fileset);
    }
 
    /* Join in the effort to repartition them. */
    for (i = 1; i < old_nbatch; ++i)
    {
        MinimalTuple tuple;
        uint32      hashvalue;
 
        /* Scan one partition from the previous generation. */
        sts_begin_parallel_scan(old_inner_tuples[i]);
        while ((tuple = sts_parallel_scan_next(old_inner_tuples[i], &hashvalue)))
        {
            size_t      tuple_size = MAXALIGN(HJTUPLE_OVERHEAD + tuple->t_len);
            int         bucketno;
            int         batchno;
 
            /* Decide which partition it goes to in the new generation. */
            ExecHashGetBucketAndBatch(hashtable, hashvalue, &bucketno,
                                      &batchno);
 
            hashtable->batches[batchno].estimated_size += tuple_size;
            ++hashtable->batches[batchno].ntuples;
            ++hashtable->batches[i].old_ntuples;
 
            /* Store the tuple its new batch. */
            sts_puttuple(hashtable->batches[batchno].inner_tuples,
                         &hashvalue, tuple);
 
            CHECK_FOR_INTERRUPTS();
        }
        sts_end_parallel_scan(old_inner_tuples[i]);
    }
 
    pfree(old_inner_tuples);
}

References HashJoinTableData::area, HashJoinTableData::batches, CHECK_FOR_INTERRUPTS, dsa_get_address(), ParallelHashJoinBatchAccessor::estimated_size, ExecHashGetBucketAndBatch(), ParallelHashJoinState::fileset, HJTUPLE_OVERHEAD, i, ParallelHashJoinBatchAccessor::inner_tuples, MAXALIGN, NthParallelHashJoinBatch, ParallelHashJoinBatchAccessor::ntuples, ParallelHashJoinState::old_batches, ParallelHashJoinState::old_nbatch, ParallelHashJoinBatchAccessor::old_ntuples, palloc0_array, HashJoinTableData::parallel_state, ParallelHashJoinBatchInner, ParallelWorkerNumber, pfree(), sts_attach(), sts_begin_parallel_scan(), sts_end_parallel_scan(), sts_parallel_scan_next(), sts_puttuple(), and MinimalTupleData::t_len.

Referenced by ExecParallelHashIncreaseNumBatches().

ExecParallelHashTableAlloc()

void ExecParallelHashTableAlloc	(	HashJoinTable	hashtable,
		int	batchno
	)

Definition at line 3259 of file nodeHash.c.

{
    ParallelHashJoinBatch *batch = hashtable->batches[batchno].shared;
    dsa_pointer_atomic *buckets;
    int         nbuckets = hashtable->parallel_state->nbuckets;
    int         i;
 
    batch->buckets =
        dsa_allocate(hashtable->area, sizeof(dsa_pointer_atomic) * nbuckets);
    buckets = (dsa_pointer_atomic *)
        dsa_get_address(hashtable->area, batch->buckets);
    for (i = 0; i < nbuckets; ++i)
        dsa_pointer_atomic_init(&buckets[i], InvalidDsaPointer);
}

References HashJoinTableData::area, HashJoinTableData::batches, ParallelHashJoinBatch::buckets, dsa_allocate, dsa_get_address(), dsa_pointer_atomic_init, i, InvalidDsaPointer, ParallelHashJoinState::nbuckets, HashJoinTableData::parallel_state, and ParallelHashJoinBatchAccessor::shared.

Referenced by ExecHashTableCreate(), and ExecParallelHashJoinNewBatch().

ExecParallelHashTableInsert()

void ExecParallelHashTableInsert	(	HashJoinTable	hashtable,
		TupleTableSlot *	slot,
		uint32	hashvalue
	)

Definition at line 1711 of file nodeHash.c.

{
    bool        shouldFree;
    MinimalTuple tuple = ExecFetchSlotMinimalTuple(slot, &shouldFree);
    dsa_pointer shared;
    int         bucketno;
    int         batchno;
 
retry:
    ExecHashGetBucketAndBatch(hashtable, hashvalue, &bucketno, &batchno);
 
    if (batchno == 0)
    {
        HashJoinTuple hashTuple;
 
        /* Try to load it into memory. */
        Assert(BarrierPhase(&hashtable->parallel_state->build_barrier) ==
               PHJ_BUILD_HASH_INNER);
        hashTuple = ExecParallelHashTupleAlloc(hashtable,
                                               HJTUPLE_OVERHEAD + tuple->t_len,
                                               &shared);
        if (hashTuple == NULL)
            goto retry;
 
        /* Store the hash value in the HashJoinTuple header. */
        hashTuple->hashvalue = hashvalue;
        memcpy(HJTUPLE_MINTUPLE(hashTuple), tuple, tuple->t_len);
        HeapTupleHeaderClearMatch(HJTUPLE_MINTUPLE(hashTuple));
 
        /* Push it onto the front of the bucket's list */
        ExecParallelHashPushTuple(&hashtable->buckets.shared[bucketno],
                                  hashTuple, shared);
    }
    else
    {
        size_t      tuple_size = MAXALIGN(HJTUPLE_OVERHEAD + tuple->t_len);
 
        Assert(batchno > 0);
 
        /* Try to preallocate space in the batch if necessary. */
        if (hashtable->batches[batchno].preallocated < tuple_size)
        {
            if (!ExecParallelHashTuplePrealloc(hashtable, batchno, tuple_size))
                goto retry;
        }
 
        Assert(hashtable->batches[batchno].preallocated >= tuple_size);
        hashtable->batches[batchno].preallocated -= tuple_size;
        sts_puttuple(hashtable->batches[batchno].inner_tuples, &hashvalue,
                     tuple);
    }
    ++hashtable->batches[batchno].ntuples;
 
    if (shouldFree)
        heap_free_minimal_tuple(tuple);
}

References Assert(), BarrierPhase(), HashJoinTableData::batches, HashJoinTableData::buckets, ParallelHashJoinState::build_barrier, ExecFetchSlotMinimalTuple(), ExecHashGetBucketAndBatch(), ExecParallelHashPushTuple(), ExecParallelHashTupleAlloc(), ExecParallelHashTuplePrealloc(), HashJoinTupleData::hashvalue, heap_free_minimal_tuple(), HeapTupleHeaderClearMatch, HJTUPLE_MINTUPLE, HJTUPLE_OVERHEAD, ParallelHashJoinBatchAccessor::inner_tuples, MAXALIGN, ParallelHashJoinBatchAccessor::ntuples, HashJoinTableData::parallel_state, PHJ_BUILD_HASH_INNER, ParallelHashJoinBatchAccessor::preallocated, HashJoinTableData::shared, sts_puttuple(), and MinimalTupleData::t_len.

Referenced by MultiExecParallelHash().

ExecParallelHashTableInsertCurrentBatch()

void ExecParallelHashTableInsertCurrentBatch	(	HashJoinTable	hashtable,
		TupleTableSlot *	slot,
		uint32	hashvalue
	)

Definition at line 1777 of file nodeHash.c.

{
    bool        shouldFree;
    MinimalTuple tuple = ExecFetchSlotMinimalTuple(slot, &shouldFree);
    HashJoinTuple hashTuple;
    dsa_pointer shared;
    int         batchno;
    int         bucketno;
 
    ExecHashGetBucketAndBatch(hashtable, hashvalue, &bucketno, &batchno);
    Assert(batchno == hashtable->curbatch);
    hashTuple = ExecParallelHashTupleAlloc(hashtable,
                                           HJTUPLE_OVERHEAD + tuple->t_len,
                                           &shared);
    hashTuple->hashvalue = hashvalue;
    memcpy(HJTUPLE_MINTUPLE(hashTuple), tuple, tuple->t_len);
    HeapTupleHeaderClearMatch(HJTUPLE_MINTUPLE(hashTuple));
    ExecParallelHashPushTuple(&hashtable->buckets.shared[bucketno],
                              hashTuple, shared);
 
    if (shouldFree)
        heap_free_minimal_tuple(tuple);
}

References Assert(), HashJoinTableData::buckets, HashJoinTableData::curbatch, ExecFetchSlotMinimalTuple(), ExecHashGetBucketAndBatch(), ExecParallelHashPushTuple(), ExecParallelHashTupleAlloc(), HashJoinTupleData::hashvalue, heap_free_minimal_tuple(), HeapTupleHeaderClearMatch, HJTUPLE_MINTUPLE, HJTUPLE_OVERHEAD, HashJoinTableData::shared, and MinimalTupleData::t_len.

Referenced by ExecParallelHashJoinNewBatch().

ExecParallelHashTableSetCurrentBatch()

void ExecParallelHashTableSetCurrentBatch	(	HashJoinTable	hashtable,
		int	batchno
	)

Definition at line 3469 of file nodeHash.c.

{
    Assert(hashtable->batches[batchno].shared->buckets != InvalidDsaPointer);
 
    hashtable->curbatch = batchno;
    hashtable->buckets.shared = (dsa_pointer_atomic *)
        dsa_get_address(hashtable->area,
                        hashtable->batches[batchno].shared->buckets);
    hashtable->nbuckets = hashtable->parallel_state->nbuckets;
    hashtable->log2_nbuckets = my_log2(hashtable->nbuckets);
    hashtable->current_chunk = NULL;
    hashtable->current_chunk_shared = InvalidDsaPointer;
    hashtable->batches[batchno].at_least_one_chunk = false;
}

References HashJoinTableData::area, Assert(), ParallelHashJoinBatchAccessor::at_least_one_chunk, HashJoinTableData::batches, ParallelHashJoinBatch::buckets, HashJoinTableData::buckets, HashJoinTableData::curbatch, HashJoinTableData::current_chunk, HashJoinTableData::current_chunk_shared, dsa_get_address(), InvalidDsaPointer, HashJoinTableData::log2_nbuckets, my_log2(), ParallelHashJoinState::nbuckets, HashJoinTableData::nbuckets, HashJoinTableData::parallel_state, ParallelHashJoinBatchAccessor::shared, and HashJoinTableData::shared.

Referenced by ExecParallelHashIncreaseNumBatches(), ExecParallelHashIncreaseNumBuckets(), ExecParallelHashJoinNewBatch(), and MultiExecParallelHash().

ExecParallelHashTupleAlloc()

static HashJoinTuple ExecParallelHashTupleAlloc ( HashJoinTable  hashtable, size_t  size, dsa_pointer *  shared  )

static

Definition at line 2946 of file nodeHash.c.

{
    ParallelHashJoinState *pstate = hashtable->parallel_state;
    dsa_pointer chunk_shared;
    HashMemoryChunk chunk;
    Size        chunk_size;
    HashJoinTuple result;
    int         curbatch = hashtable->curbatch;
 
    size = MAXALIGN(size);
 
    /*
     * Fast path: if there is enough space in this backend's current chunk,
     * then we can allocate without any locking.
     */
    chunk = hashtable->current_chunk;
    if (chunk != NULL &&
        size <= HASH_CHUNK_THRESHOLD &&
        chunk->maxlen - chunk->used >= size)
    {
 
        chunk_shared = hashtable->current_chunk_shared;
        Assert(chunk == dsa_get_address(hashtable->area, chunk_shared));
        *shared = chunk_shared + HASH_CHUNK_HEADER_SIZE + chunk->used;
        result = (HashJoinTuple) (HASH_CHUNK_DATA(chunk) + chunk->used);
        chunk->used += size;
 
        Assert(chunk->used <= chunk->maxlen);
        Assert(result == dsa_get_address(hashtable->area, *shared));
 
        return result;
    }
 
    /* Slow path: try to allocate a new chunk. */
    LWLockAcquire(&pstate->lock, LW_EXCLUSIVE);
 
    /*
     * Check if we need to help increase the number of buckets or batches.
     */
    if (pstate->growth == PHJ_GROWTH_NEED_MORE_BATCHES ||
        pstate->growth == PHJ_GROWTH_NEED_MORE_BUCKETS)
    {
        ParallelHashGrowth growth = pstate->growth;
 
        hashtable->current_chunk = NULL;
        LWLockRelease(&pstate->lock);
 
        /* Another participant has commanded us to help grow. */
        if (growth == PHJ_GROWTH_NEED_MORE_BATCHES)
            ExecParallelHashIncreaseNumBatches(hashtable);
        else if (growth == PHJ_GROWTH_NEED_MORE_BUCKETS)
            ExecParallelHashIncreaseNumBuckets(hashtable);
 
        /* The caller must retry. */
        return NULL;
    }
 
    /* Oversized tuples get their own chunk. */
    if (size > HASH_CHUNK_THRESHOLD)
        chunk_size = size + HASH_CHUNK_HEADER_SIZE;
    else
        chunk_size = HASH_CHUNK_SIZE;
 
    /* Check if it's time to grow batches or buckets. */
    if (pstate->growth != PHJ_GROWTH_DISABLED)
    {
        Assert(curbatch == 0);
        Assert(BarrierPhase(&pstate->build_barrier) == PHJ_BUILD_HASH_INNER);
 
        /*
         * Check if our space limit would be exceeded.  To avoid choking on
         * very large tuples or very low hash_mem setting, we'll always allow
         * each backend to allocate at least one chunk.
         */
        if (hashtable->batches[0].at_least_one_chunk &&
            hashtable->batches[0].shared->size +
            chunk_size > pstate->space_allowed)
        {
            pstate->growth = PHJ_GROWTH_NEED_MORE_BATCHES;
            hashtable->batches[0].shared->space_exhausted = true;
            LWLockRelease(&pstate->lock);
 
            return NULL;
        }
 
        /* Check if our load factor limit would be exceeded. */
        if (hashtable->nbatch == 1)
        {
            hashtable->batches[0].shared->ntuples += hashtable->batches[0].ntuples;
            hashtable->batches[0].ntuples = 0;
            /* Guard against integer overflow and alloc size overflow */
            if (hashtable->batches[0].shared->ntuples + 1 >
                hashtable->nbuckets * NTUP_PER_BUCKET &&
                hashtable->nbuckets < (INT_MAX / 2) &&
                hashtable->nbuckets * 2 <=
                MaxAllocSize / sizeof(dsa_pointer_atomic))
            {
                pstate->growth = PHJ_GROWTH_NEED_MORE_BUCKETS;
                LWLockRelease(&pstate->lock);
 
                return NULL;
            }
        }
    }
 
    /* We are cleared to allocate a new chunk. */
    chunk_shared = dsa_allocate(hashtable->area, chunk_size);
    hashtable->batches[curbatch].shared->size += chunk_size;
    hashtable->batches[curbatch].at_least_one_chunk = true;
 
    /* Set up the chunk. */
    chunk = (HashMemoryChunk) dsa_get_address(hashtable->area, chunk_shared);
    *shared = chunk_shared + HASH_CHUNK_HEADER_SIZE;
    chunk->maxlen = chunk_size - HASH_CHUNK_HEADER_SIZE;
    chunk->used = size;
 
    /*
     * Push it onto the list of chunks, so that it can be found if we need to
     * increase the number of buckets or batches (batch 0 only) and later for
     * freeing the memory (all batches).
     */
    chunk->next.shared = hashtable->batches[curbatch].shared->chunks;
    hashtable->batches[curbatch].shared->chunks = chunk_shared;
 
    if (size <= HASH_CHUNK_THRESHOLD)
    {
        /*
         * Make this the current chunk so that we can use the fast path to
         * fill the rest of it up in future calls.
         */
        hashtable->current_chunk = chunk;
        hashtable->current_chunk_shared = chunk_shared;
    }
    LWLockRelease(&pstate->lock);
 
    Assert(HASH_CHUNK_DATA(chunk) == dsa_get_address(hashtable->area, *shared));
    result = (HashJoinTuple) HASH_CHUNK_DATA(chunk);
 
    return result;
}

References HashJoinTableData::area, Assert(), ParallelHashJoinBatchAccessor::at_least_one_chunk, BarrierPhase(), HashJoinTableData::batches, ParallelHashJoinState::build_barrier, ParallelHashJoinBatch::chunks, HashJoinTableData::curbatch, HashJoinTableData::current_chunk, HashJoinTableData::current_chunk_shared, dsa_allocate, dsa_get_address(), ExecParallelHashIncreaseNumBatches(), ExecParallelHashIncreaseNumBuckets(), ParallelHashJoinState::growth, HASH_CHUNK_DATA, HASH_CHUNK_HEADER_SIZE, HASH_CHUNK_SIZE, HASH_CHUNK_THRESHOLD, ParallelHashJoinState::lock, LW_EXCLUSIVE, LWLockAcquire(), LWLockRelease(), MAXALIGN, MaxAllocSize, HashMemoryChunkData::maxlen, HashJoinTableData::nbatch, HashJoinTableData::nbuckets, HashMemoryChunkData::next, NTUP_PER_BUCKET, ParallelHashJoinBatch::ntuples, ParallelHashJoinBatchAccessor::ntuples, HashJoinTableData::parallel_state, PHJ_BUILD_HASH_INNER, PHJ_GROWTH_DISABLED, PHJ_GROWTH_NEED_MORE_BATCHES, PHJ_GROWTH_NEED_MORE_BUCKETS, HashMemoryChunkData::shared, ParallelHashJoinBatchAccessor::shared, ParallelHashJoinBatch::size, ParallelHashJoinState::space_allowed, ParallelHashJoinBatch::space_exhausted, and HashMemoryChunkData::used.

Referenced by ExecParallelHashRepartitionFirst(), ExecParallelHashTableInsert(), and ExecParallelHashTableInsertCurrentBatch().

ExecParallelHashTuplePrealloc()

static bool ExecParallelHashTuplePrealloc ( HashJoinTable  hashtable, int  batchno, size_t  size  )

static

Definition at line 3531 of file nodeHash.c.

{
    ParallelHashJoinState *pstate = hashtable->parallel_state;
    ParallelHashJoinBatchAccessor *batch = &hashtable->batches[batchno];
    size_t      want = Max(size, HASH_CHUNK_SIZE - HASH_CHUNK_HEADER_SIZE);
 
    Assert(batchno > 0);
    Assert(batchno < hashtable->nbatch);
    Assert(size == MAXALIGN(size));
 
    LWLockAcquire(&pstate->lock, LW_EXCLUSIVE);
 
    /* Has another participant commanded us to help grow? */
    if (pstate->growth == PHJ_GROWTH_NEED_MORE_BATCHES ||
        pstate->growth == PHJ_GROWTH_NEED_MORE_BUCKETS)
    {
        ParallelHashGrowth growth = pstate->growth;
 
        LWLockRelease(&pstate->lock);
        if (growth == PHJ_GROWTH_NEED_MORE_BATCHES)
            ExecParallelHashIncreaseNumBatches(hashtable);
        else if (growth == PHJ_GROWTH_NEED_MORE_BUCKETS)
            ExecParallelHashIncreaseNumBuckets(hashtable);
 
        return false;
    }
 
    if (pstate->growth != PHJ_GROWTH_DISABLED &&
        batch->at_least_one_chunk &&
        (batch->shared->estimated_size + want + HASH_CHUNK_HEADER_SIZE
         > pstate->space_allowed))
    {
        /*
         * We have determined that this batch would exceed the space budget if
         * loaded into memory.  Command all participants to help repartition.
         */
        batch->shared->space_exhausted = true;
        pstate->growth = PHJ_GROWTH_NEED_MORE_BATCHES;
        LWLockRelease(&pstate->lock);
 
        return false;
    }
 
    batch->at_least_one_chunk = true;
    batch->shared->estimated_size += want + HASH_CHUNK_HEADER_SIZE;
    batch->preallocated = want;
    LWLockRelease(&pstate->lock);
 
    return true;
}

References Assert(), ParallelHashJoinBatchAccessor::at_least_one_chunk, HashJoinTableData::batches, ParallelHashJoinBatch::estimated_size, ExecParallelHashIncreaseNumBatches(), ExecParallelHashIncreaseNumBuckets(), ParallelHashJoinState::growth, HASH_CHUNK_HEADER_SIZE, HASH_CHUNK_SIZE, ParallelHashJoinState::lock, LW_EXCLUSIVE, LWLockAcquire(), LWLockRelease(), Max, MAXALIGN, HashJoinTableData::parallel_state, PHJ_GROWTH_DISABLED, PHJ_GROWTH_NEED_MORE_BATCHES, PHJ_GROWTH_NEED_MORE_BUCKETS, ParallelHashJoinBatchAccessor::preallocated, ParallelHashJoinBatchAccessor::shared, ParallelHashJoinState::space_allowed, and ParallelHashJoinBatch::space_exhausted.

Referenced by ExecParallelHashTableInsert().

ExecParallelPrepHashTableForUnmatched()

bool ExecParallelPrepHashTableForUnmatched

(

HashJoinState *

hjstate

)

Definition at line 2094 of file nodeHash.c.

{
    HashJoinTable hashtable = hjstate->hj_HashTable;
    int         curbatch = hashtable->curbatch;
    ParallelHashJoinBatch *batch = hashtable->batches[curbatch].shared;
 
    Assert(BarrierPhase(&batch->batch_barrier) == PHJ_BATCH_PROBE);
 
    /*
     * It would not be deadlock-free to wait on the batch barrier, because it
     * is in PHJ_BATCH_PROBE phase, and thus processes attached to it have
     * already emitted tuples.  Therefore, we'll hold a wait-free election:
     * only one process can continue to the next phase, and all others detach
     * from this batch.  They can still go any work on other batches, if there
     * are any.
     */
    if (!BarrierArriveAndDetachExceptLast(&batch->batch_barrier))
    {
        /* This process considers the batch to be done. */
        hashtable->batches[hashtable->curbatch].done = true;
 
        /* Make sure any temporary files are closed. */
        sts_end_parallel_scan(hashtable->batches[curbatch].inner_tuples);
        sts_end_parallel_scan(hashtable->batches[curbatch].outer_tuples);
 
        /*
         * Track largest batch we've seen, which would normally happen in
         * ExecHashTableDetachBatch().
         */
        hashtable->spacePeak =
            Max(hashtable->spacePeak,
                batch->size + sizeof(dsa_pointer_atomic) * hashtable->nbuckets);
        hashtable->curbatch = -1;
        return false;
    }
 
    /* Now we are alone with this batch. */
    Assert(BarrierPhase(&batch->batch_barrier) == PHJ_BATCH_SCAN);
 
    /*
     * Has another process decided to give up early and command all processes
     * to skip the unmatched scan?
     */
    if (batch->skip_unmatched)
    {
        hashtable->batches[hashtable->curbatch].done = true;
        ExecHashTableDetachBatch(hashtable);
        return false;
    }
 
    /* Now prepare the process local state, just as for non-parallel join. */
    ExecPrepHashTableForUnmatched(hjstate);
 
    return true;
}

References Assert(), BarrierArriveAndDetachExceptLast(), BarrierPhase(), ParallelHashJoinBatch::batch_barrier, HashJoinTableData::batches, HashJoinTableData::curbatch, ParallelHashJoinBatchAccessor::done, ExecHashTableDetachBatch(), ExecPrepHashTableForUnmatched(), HashJoinState::hj_HashTable, ParallelHashJoinBatchAccessor::inner_tuples, Max, HashJoinTableData::nbuckets, ParallelHashJoinBatchAccessor::outer_tuples, PHJ_BATCH_PROBE, PHJ_BATCH_SCAN, ParallelHashJoinBatchAccessor::shared, ParallelHashJoinBatch::size, ParallelHashJoinBatch::skip_unmatched, HashJoinTableData::spacePeak, and sts_end_parallel_scan().

Referenced by ExecHashJoinImpl().

ExecParallelScanHashBucket()

bool ExecParallelScanHashBucket	(	HashJoinState *	hjstate,
		ExprContext *	econtext
	)

Definition at line 2022 of file nodeHash.c.

{
    ExprState  *hjclauses = hjstate->hashclauses;
    HashJoinTable hashtable = hjstate->hj_HashTable;
    HashJoinTuple hashTuple = hjstate->hj_CurTuple;
    uint32      hashvalue = hjstate->hj_CurHashValue;
 
    /*
     * hj_CurTuple is the address of the tuple last returned from the current
     * bucket, or NULL if it's time to start scanning a new bucket.
     */
    if (hashTuple != NULL)
        hashTuple = ExecParallelHashNextTuple(hashtable, hashTuple);
    else
        hashTuple = ExecParallelHashFirstTuple(hashtable,
                                               hjstate->hj_CurBucketNo);
 
    while (hashTuple != NULL)
    {
        if (hashTuple->hashvalue == hashvalue)
        {
            TupleTableSlot *inntuple;
 
            /* insert hashtable's tuple into exec slot so ExecQual sees it */
            inntuple = ExecStoreMinimalTuple(HJTUPLE_MINTUPLE(hashTuple),
                                             hjstate->hj_HashTupleSlot,
                                             false);    /* do not pfree */
            econtext->ecxt_innertuple = inntuple;
 
            if (ExecQualAndReset(hjclauses, econtext))
            {
                hjstate->hj_CurTuple = hashTuple;
                return true;
            }
        }
 
        hashTuple = ExecParallelHashNextTuple(hashtable, hashTuple);
    }
 
    /*
     * no match
     */
    return false;
}

References ExprContext::ecxt_innertuple, ExecParallelHashFirstTuple(), ExecParallelHashNextTuple(), ExecQualAndReset(), ExecStoreMinimalTuple(), HashJoinState::hashclauses, HashJoinTupleData::hashvalue, HashJoinState::hj_CurBucketNo, HashJoinState::hj_CurHashValue, HashJoinState::hj_CurTuple, HashJoinState::hj_HashTable, HashJoinState::hj_HashTupleSlot, and HJTUPLE_MINTUPLE.

Referenced by ExecHashJoinImpl().

ExecParallelScanHashTableForUnmatched()

bool ExecParallelScanHashTableForUnmatched	(	HashJoinState *	hjstate,
		ExprContext *	econtext
	)

Definition at line 2233 of file nodeHash.c.

{
    HashJoinTable hashtable = hjstate->hj_HashTable;
    HashJoinTuple hashTuple = hjstate->hj_CurTuple;
 
    for (;;)
    {
        /*
         * hj_CurTuple is the address of the tuple last returned from the
         * current bucket, or NULL if it's time to start scanning a new
         * bucket.
         */
        if (hashTuple != NULL)
            hashTuple = ExecParallelHashNextTuple(hashtable, hashTuple);
        else if (hjstate->hj_CurBucketNo < hashtable->nbuckets)
            hashTuple = ExecParallelHashFirstTuple(hashtable,
                                                   hjstate->hj_CurBucketNo++);
        else
            break;              /* finished all buckets */
 
        while (hashTuple != NULL)
        {
            if (!HeapTupleHeaderHasMatch(HJTUPLE_MINTUPLE(hashTuple)))
            {
                TupleTableSlot *inntuple;
 
                /* insert hashtable's tuple into exec slot */
                inntuple = ExecStoreMinimalTuple(HJTUPLE_MINTUPLE(hashTuple),
                                                 hjstate->hj_HashTupleSlot,
                                                 false);    /* do not pfree */
                econtext->ecxt_innertuple = inntuple;
 
                /*
                 * Reset temp memory each time; although this function doesn't
                 * do any qual eval, the caller will, so let's keep it
                 * parallel to ExecScanHashBucket.
                 */
                ResetExprContext(econtext);
 
                hjstate->hj_CurTuple = hashTuple;
                return true;
            }
 
            hashTuple = ExecParallelHashNextTuple(hashtable, hashTuple);
        }
 
        /* allow this loop to be cancellable */
        CHECK_FOR_INTERRUPTS();
    }
 
    /*
     * no more unmatched tuples
     */
    return false;
}

References CHECK_FOR_INTERRUPTS, ExprContext::ecxt_innertuple, ExecParallelHashFirstTuple(), ExecParallelHashNextTuple(), ExecStoreMinimalTuple(), HeapTupleHeaderHasMatch, HashJoinState::hj_CurBucketNo, HashJoinState::hj_CurTuple, HashJoinState::hj_HashTable, HashJoinState::hj_HashTupleSlot, HJTUPLE_MINTUPLE, HashJoinTableData::nbuckets, and ResetExprContext.

Referenced by ExecHashJoinImpl().

ExecPrepHashTableForUnmatched()

void ExecPrepHashTableForUnmatched

(

HashJoinState *

hjstate

)

Definition at line 2073 of file nodeHash.c.

{
    /*----------
     * During this scan we use the HashJoinState fields as follows:
     *
     * hj_CurBucketNo: next regular bucket to scan
     * hj_CurSkewBucketNo: next skew bucket (an index into skewBucketNums)
     * hj_CurTuple: last tuple returned, or NULL to start next bucket
     *----------
     */
    hjstate->hj_CurBucketNo = 0;
    hjstate->hj_CurSkewBucketNo = 0;
    hjstate->hj_CurTuple = NULL;
}

References HashJoinState::hj_CurBucketNo, HashJoinState::hj_CurSkewBucketNo, and HashJoinState::hj_CurTuple.

Referenced by ExecHashJoinImpl(), and ExecParallelPrepHashTableForUnmatched().

ExecReScanHash()

void ExecReScanHash

(

HashState *

node

)

Definition at line 2350 of file nodeHash.c.

{
    PlanState  *outerPlan = outerPlanState(node);
 
    /*
     * if chgParam of subnode is not null then plan will be re-scanned by
     * first ExecProcNode.
     */
    if (outerPlan->chgParam == NULL)
        ExecReScan(outerPlan);
}

References ExecReScan(), outerPlan, and outerPlanState.

Referenced by ExecReScan().

ExecScanHashBucket()

bool ExecScanHashBucket	(	HashJoinState *	hjstate,
		ExprContext *	econtext
	)

Definition at line 1961 of file nodeHash.c.

{
    ExprState  *hjclauses = hjstate->hashclauses;
    HashJoinTable hashtable = hjstate->hj_HashTable;
    HashJoinTuple hashTuple = hjstate->hj_CurTuple;
    uint32      hashvalue = hjstate->hj_CurHashValue;
 
    /*
     * hj_CurTuple is the address of the tuple last returned from the current
     * bucket, or NULL if it's time to start scanning a new bucket.
     *
     * If the tuple hashed to a skew bucket then scan the skew bucket
     * otherwise scan the standard hashtable bucket.
     */
    if (hashTuple != NULL)
        hashTuple = hashTuple->next.unshared;
    else if (hjstate->hj_CurSkewBucketNo != INVALID_SKEW_BUCKET_NO)
        hashTuple = hashtable->skewBucket[hjstate->hj_CurSkewBucketNo]->tuples;
    else
        hashTuple = hashtable->buckets.unshared[hjstate->hj_CurBucketNo];
 
    while (hashTuple != NULL)
    {
        if (hashTuple->hashvalue == hashvalue)
        {
            TupleTableSlot *inntuple;
 
            /* insert hashtable's tuple into exec slot so ExecQual sees it */
            inntuple = ExecStoreMinimalTuple(HJTUPLE_MINTUPLE(hashTuple),
                                             hjstate->hj_HashTupleSlot,
                                             false);    /* do not pfree */
            econtext->ecxt_innertuple = inntuple;
 
            if (ExecQualAndReset(hjclauses, econtext))
            {
                hjstate->hj_CurTuple = hashTuple;
                return true;
            }
        }
 
        hashTuple = hashTuple->next.unshared;
    }
 
    /*
     * no match
     */
    return false;
}

References HashJoinTableData::buckets, ExprContext::ecxt_innertuple, ExecQualAndReset(), ExecStoreMinimalTuple(), HashJoinState::hashclauses, HashJoinTupleData::hashvalue, HashJoinState::hj_CurBucketNo, HashJoinState::hj_CurHashValue, HashJoinState::hj_CurSkewBucketNo, HashJoinState::hj_CurTuple, HashJoinState::hj_HashTable, HashJoinState::hj_HashTupleSlot, HJTUPLE_MINTUPLE, INVALID_SKEW_BUCKET_NO, HashJoinTupleData::next, HashJoinTableData::skewBucket, HashSkewBucket::tuples, HashJoinTupleData::unshared, and HashJoinTableData::unshared.

Referenced by ExecHashJoinImpl().

ExecScanHashTableForUnmatched()

bool ExecScanHashTableForUnmatched	(	HashJoinState *	hjstate,
		ExprContext *	econtext
	)

Definition at line 2159 of file nodeHash.c.

{
    HashJoinTable hashtable = hjstate->hj_HashTable;
    HashJoinTuple hashTuple = hjstate->hj_CurTuple;
 
    for (;;)
    {
        /*
         * hj_CurTuple is the address of the tuple last returned from the
         * current bucket, or NULL if it's time to start scanning a new
         * bucket.
         */
        if (hashTuple != NULL)
            hashTuple = hashTuple->next.unshared;
        else if (hjstate->hj_CurBucketNo < hashtable->nbuckets)
        {
            hashTuple = hashtable->buckets.unshared[hjstate->hj_CurBucketNo];
            hjstate->hj_CurBucketNo++;
        }
        else if (hjstate->hj_CurSkewBucketNo < hashtable->nSkewBuckets)
        {
            int         j = hashtable->skewBucketNums[hjstate->hj_CurSkewBucketNo];
 
            hashTuple = hashtable->skewBucket[j]->tuples;
            hjstate->hj_CurSkewBucketNo++;
        }
        else
            break;              /* finished all buckets */
 
        while (hashTuple != NULL)
        {
            if (!HeapTupleHeaderHasMatch(HJTUPLE_MINTUPLE(hashTuple)))
            {
                TupleTableSlot *inntuple;
 
                /* insert hashtable's tuple into exec slot */
                inntuple = ExecStoreMinimalTuple(HJTUPLE_MINTUPLE(hashTuple),
                                                 hjstate->hj_HashTupleSlot,
                                                 false);    /* do not pfree */
                econtext->ecxt_innertuple = inntuple;
 
                /*
                 * Reset temp memory each time; although this function doesn't
                 * do any qual eval, the caller will, so let's keep it
                 * parallel to ExecScanHashBucket.
                 */
                ResetExprContext(econtext);
 
                hjstate->hj_CurTuple = hashTuple;
                return true;
            }
 
            hashTuple = hashTuple->next.unshared;
        }
 
        /* allow this loop to be cancellable */
        CHECK_FOR_INTERRUPTS();
    }
 
    /*
     * no more unmatched tuples
     */
    return false;
}

References HashJoinTableData::buckets, CHECK_FOR_INTERRUPTS, ExprContext::ecxt_innertuple, ExecStoreMinimalTuple(), HeapTupleHeaderHasMatch, HashJoinState::hj_CurBucketNo, HashJoinState::hj_CurSkewBucketNo, HashJoinState::hj_CurTuple, HashJoinState::hj_HashTable, HashJoinState::hj_HashTupleSlot, HJTUPLE_MINTUPLE, j, HashJoinTableData::nbuckets, HashJoinTupleData::next, HashJoinTableData::nSkewBuckets, ResetExprContext, HashJoinTableData::skewBucket, HashJoinTableData::skewBucketNums, HashSkewBucket::tuples, HashJoinTupleData::unshared, and HashJoinTableData::unshared.

Referenced by ExecHashJoinImpl().

ExecShutdownHash()

void ExecShutdownHash

(

HashState *

node

)

Definition at line 2801 of file nodeHash.c.

{
    /* Allocate save space if EXPLAIN'ing and we didn't do so already */
    if (node->ps.instrument && !node->hinstrument)
        node->hinstrument = palloc0_object(HashInstrumentation);
    /* Now accumulate data for the current (final) hash table */
    if (node->hinstrument && node->hashtable)
        ExecHashAccumInstrumentation(node->hinstrument, node->hashtable);
}

References ExecHashAccumInstrumentation(), HashState::hashtable, HashState::hinstrument, PlanState::instrument, palloc0_object, and HashState::ps.

Referenced by ExecShutdownNode_walker().

get_hash_memory_limit()

size_t get_hash_memory_limit

(

void

)

Definition at line 3592 of file nodeHash.c.

{
    double      mem_limit;
 
    /* Do initial calculation in double arithmetic */
    mem_limit = (double) work_mem * hash_mem_multiplier * 1024.0;
 
    /* Clamp in case it doesn't fit in size_t */
    mem_limit = Min(mem_limit, (double) SIZE_MAX);
 
    return (size_t) mem_limit;
}

References hash_mem_multiplier, Min, and work_mem.

Referenced by BuildTupleHashTableExt(), choose_hashed_setop(), consider_groupingsets_paths(), cost_memoize_rescan(), create_unique_path(), ExecChooseHashTableSize(), ExecInitMemoize(), ExecParallelHashIncreaseNumBatches(), final_cost_hashjoin(), hash_agg_set_limits(), hash_choose_num_partitions(), subpath_is_hashable(), and subplan_is_hashable().

MultiExecHash()

Node* MultiExecHash

(

HashState *

node

)

Definition at line 106 of file nodeHash.c.

{
    /* must provide our own instrumentation support */
    if (node->ps.instrument)
        InstrStartNode(node->ps.instrument);
 
    if (node->parallel_state != NULL)
        MultiExecParallelHash(node);
    else
        MultiExecPrivateHash(node);
 
    /* must provide our own instrumentation support */
    if (node->ps.instrument)
        InstrStopNode(node->ps.instrument, node->hashtable->partialTuples);
 
    /*
     * We do not return the hash table directly because it's not a subtype of
     * Node, and so would violate the MultiExecProcNode API.  Instead, our
     * parent Hashjoin node is expected to know how to fish it out of our node
     * state.  Ugly but not really worth cleaning up, since Hashjoin knows
     * quite a bit more about Hash besides that.
     */
    return NULL;
}

References HashState::hashtable, InstrStartNode(), InstrStopNode(), PlanState::instrument, MultiExecParallelHash(), MultiExecPrivateHash(), HashState::parallel_state, HashJoinTableData::partialTuples, and HashState::ps.

Referenced by MultiExecProcNode().

MultiExecParallelHash()

static void MultiExecParallelHash ( HashState *  node )

static

Definition at line 215 of file nodeHash.c.

{
    ParallelHashJoinState *pstate;
    PlanState  *outerNode;
    List       *hashkeys;
    HashJoinTable hashtable;
    TupleTableSlot *slot;
    ExprContext *econtext;
    uint32      hashvalue;
    Barrier    *build_barrier;
    int         i;
 
    /*
     * get state info from node
     */
    outerNode = outerPlanState(node);
    hashtable = node->hashtable;
 
    /*
     * set expression context
     */
    hashkeys = node->hashkeys;
    econtext = node->ps.ps_ExprContext;
 
    /*
     * Synchronize the parallel hash table build.  At this stage we know that
     * the shared hash table has been or is being set up by
     * ExecHashTableCreate(), but we don't know if our peers have returned
     * from there or are here in MultiExecParallelHash(), and if so how far
     * through they are.  To find out, we check the build_barrier phase then
     * and jump to the right step in the build algorithm.
     */
    pstate = hashtable->parallel_state;
    build_barrier = &pstate->build_barrier;
    Assert(BarrierPhase(build_barrier) >= PHJ_BUILD_ALLOCATE);
    switch (BarrierPhase(build_barrier))
    {
        case PHJ_BUILD_ALLOCATE:
 
            /*
             * Either I just allocated the initial hash table in
             * ExecHashTableCreate(), or someone else is doing that.  Either
             * way, wait for everyone to arrive here so we can proceed.
             */
            BarrierArriveAndWait(build_barrier, WAIT_EVENT_HASH_BUILD_ALLOCATE);
            /* Fall through. */
 
        case PHJ_BUILD_HASH_INNER:
 
            /*
             * It's time to begin hashing, or if we just arrived here then
             * hashing is already underway, so join in that effort.  While
             * hashing we have to be prepared to help increase the number of
             * batches or buckets at any time, and if we arrived here when
             * that was already underway we'll have to help complete that work
             * immediately so that it's safe to access batches and buckets
             * below.
             */
            if (PHJ_GROW_BATCHES_PHASE(BarrierAttach(&pstate->grow_batches_barrier)) !=
                PHJ_GROW_BATCHES_ELECT)
                ExecParallelHashIncreaseNumBatches(hashtable);
            if (PHJ_GROW_BUCKETS_PHASE(BarrierAttach(&pstate->grow_buckets_barrier)) !=
                PHJ_GROW_BUCKETS_ELECT)
                ExecParallelHashIncreaseNumBuckets(hashtable);
            ExecParallelHashEnsureBatchAccessors(hashtable);
            ExecParallelHashTableSetCurrentBatch(hashtable, 0);
            for (;;)
            {
                slot = ExecProcNode(outerNode);
                if (TupIsNull(slot))
                    break;
                econtext->ecxt_outertuple = slot;
                if (ExecHashGetHashValue(hashtable, econtext, hashkeys,
                                         false, hashtable->keepNulls,
                                         &hashvalue))
                    ExecParallelHashTableInsert(hashtable, slot, hashvalue);
                hashtable->partialTuples++;
            }
 
            /*
             * Make sure that any tuples we wrote to disk are visible to
             * others before anyone tries to load them.
             */
            for (i = 0; i < hashtable->nbatch; ++i)
                sts_end_write(hashtable->batches[i].inner_tuples);
 
            /*
             * Update shared counters.  We need an accurate total tuple count
             * to control the empty table optimization.
             */
            ExecParallelHashMergeCounters(hashtable);
 
            BarrierDetach(&pstate->grow_buckets_barrier);
            BarrierDetach(&pstate->grow_batches_barrier);
 
            /*
             * Wait for everyone to finish building and flushing files and
             * counters.
             */
            if (BarrierArriveAndWait(build_barrier,
                                     WAIT_EVENT_HASH_BUILD_HASH_INNER))
            {
                /*
                 * Elect one backend to disable any further growth.  Batches
                 * are now fixed.  While building them we made sure they'd fit
                 * in our memory budget when we load them back in later (or we
                 * tried to do that and gave up because we detected extreme
                 * skew).
                 */
                pstate->growth = PHJ_GROWTH_DISABLED;
            }
    }
 
    /*
     * We're not yet attached to a batch.  We all agree on the dimensions and
     * number of inner tuples (for the empty table optimization).
     */
    hashtable->curbatch = -1;
    hashtable->nbuckets = pstate->nbuckets;
    hashtable->log2_nbuckets = my_log2(hashtable->nbuckets);
    hashtable->totalTuples = pstate->total_tuples;
 
    /*
     * Unless we're completely done and the batch state has been freed, make
     * sure we have accessors.
     */
    if (BarrierPhase(build_barrier) < PHJ_BUILD_FREE)
        ExecParallelHashEnsureBatchAccessors(hashtable);
 
    /*
     * The next synchronization point is in ExecHashJoin's HJ_BUILD_HASHTABLE
     * case, which will bring the build phase to PHJ_BUILD_RUN (if it isn't
     * there already).
     */
    Assert(BarrierPhase(build_barrier) == PHJ_BUILD_HASH_OUTER ||
           BarrierPhase(build_barrier) == PHJ_BUILD_RUN ||
           BarrierPhase(build_barrier) == PHJ_BUILD_FREE);
}

References Assert(), BarrierArriveAndWait(), BarrierAttach(), BarrierDetach(), BarrierPhase(), HashJoinTableData::batches, ParallelHashJoinState::build_barrier, HashJoinTableData::curbatch, ExprContext::ecxt_outertuple, ExecHashGetHashValue(), ExecParallelHashEnsureBatchAccessors(), ExecParallelHashIncreaseNumBatches(), ExecParallelHashIncreaseNumBuckets(), ExecParallelHashMergeCounters(), ExecParallelHashTableInsert(), ExecParallelHashTableSetCurrentBatch(), ExecProcNode(), ParallelHashJoinState::grow_batches_barrier, ParallelHashJoinState::grow_buckets_barrier, ParallelHashJoinState::growth, HashState::hashkeys, HashState::hashtable, i, ParallelHashJoinBatchAccessor::inner_tuples, HashJoinTableData::keepNulls, HashJoinTableData::log2_nbuckets, my_log2(), HashJoinTableData::nbatch, ParallelHashJoinState::nbuckets, HashJoinTableData::nbuckets, outerPlanState, HashJoinTableData::parallel_state, HashJoinTableData::partialTuples, PHJ_BUILD_ALLOCATE, PHJ_BUILD_FREE, PHJ_BUILD_HASH_INNER, PHJ_BUILD_HASH_OUTER, PHJ_BUILD_RUN, PHJ_GROW_BATCHES_ELECT, PHJ_GROW_BATCHES_PHASE, PHJ_GROW_BUCKETS_ELECT, PHJ_GROW_BUCKETS_PHASE, PHJ_GROWTH_DISABLED, HashState::ps, PlanState::ps_ExprContext, sts_end_write(), ParallelHashJoinState::total_tuples, HashJoinTableData::totalTuples, TupIsNull, WAIT_EVENT_HASH_BUILD_ALLOCATE, and WAIT_EVENT_HASH_BUILD_HASH_INNER.

Referenced by MultiExecHash().

MultiExecPrivateHash()

static void MultiExecPrivateHash ( HashState *  node )

static

Definition at line 139 of file nodeHash.c.

{
    PlanState  *outerNode;
    List       *hashkeys;
    HashJoinTable hashtable;
    TupleTableSlot *slot;
    ExprContext *econtext;
    uint32      hashvalue;
 
    /*
     * get state info from node
     */
    outerNode = outerPlanState(node);
    hashtable = node->hashtable;
 
    /*
     * set expression context
     */
    hashkeys = node->hashkeys;
    econtext = node->ps.ps_ExprContext;
 
    /*
     * Get all tuples from the node below the Hash node and insert into the
     * hash table (or temp files).
     */
    for (;;)
    {
        slot = ExecProcNode(outerNode);
        if (TupIsNull(slot))
            break;
        /* We have to compute the hash value */
        econtext->ecxt_outertuple = slot;
        if (ExecHashGetHashValue(hashtable, econtext, hashkeys,
                                 false, hashtable->keepNulls,
                                 &hashvalue))
        {
            int         bucketNumber;
 
            bucketNumber = ExecHashGetSkewBucket(hashtable, hashvalue);
            if (bucketNumber != INVALID_SKEW_BUCKET_NO)
            {
                /* It's a skew tuple, so put it into that hash table */
                ExecHashSkewTableInsert(hashtable, slot, hashvalue,
                                        bucketNumber);
                hashtable->skewTuples += 1;
            }
            else
            {
                /* Not subject to skew optimization, so insert normally */
                ExecHashTableInsert(hashtable, slot, hashvalue);
            }
            hashtable->totalTuples += 1;
        }
    }
 
    /* resize the hash table if needed (NTUP_PER_BUCKET exceeded) */
    if (hashtable->nbuckets != hashtable->nbuckets_optimal)
        ExecHashIncreaseNumBuckets(hashtable);
 
    /* Account for the buckets in spaceUsed (reported in EXPLAIN ANALYZE) */
    hashtable->spaceUsed += hashtable->nbuckets * sizeof(HashJoinTuple);
    if (hashtable->spaceUsed > hashtable->spacePeak)
        hashtable->spacePeak = hashtable->spaceUsed;
 
    hashtable->partialTuples = hashtable->totalTuples;
}

References ExprContext::ecxt_outertuple, ExecHashGetHashValue(), ExecHashGetSkewBucket(), ExecHashIncreaseNumBuckets(), ExecHashSkewTableInsert(), ExecHashTableInsert(), ExecProcNode(), HashState::hashkeys, HashState::hashtable, INVALID_SKEW_BUCKET_NO, HashJoinTableData::keepNulls, HashJoinTableData::nbuckets, HashJoinTableData::nbuckets_optimal, outerPlanState, HashJoinTableData::partialTuples, HashState::ps, PlanState::ps_ExprContext, HashJoinTableData::skewTuples, HashJoinTableData::spacePeak, HashJoinTableData::spaceUsed, HashJoinTableData::totalTuples, and TupIsNull.

Referenced by MultiExecHash().