354 lines
9.7 KiB
C
354 lines
9.7 KiB
C
/*-------------------------------------------------------------------------
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*
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* tsm_system_time.c
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* support routines for SYSTEM_TIME tablesample method
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*
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* The desire here is to produce a random sample with as many rows as possible
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* in no more than the specified amount of time. We use a block-sampling
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* approach. To ensure that the whole relation will be visited if necessary,
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* we start at a randomly chosen block and then advance with a stride that
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* is randomly chosen but is relatively prime to the relation's nblocks.
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*
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* Because of the time dependence, this method is necessarily unrepeatable.
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* However, we do what we can to reduce surprising behavior by selecting
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* the sampling pattern just once per query, much as in tsm_system_rows.
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*
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* Portions Copyright (c) 1996-2022, PostgreSQL Global Development Group
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* Portions Copyright (c) 1994, Regents of the University of California
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*
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* IDENTIFICATION
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* contrib/tsm_system_time/tsm_system_time.c
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*
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*-------------------------------------------------------------------------
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*/
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#include "postgres.h"
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#include <math.h>
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#include "access/relscan.h"
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#include "access/tsmapi.h"
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#include "catalog/pg_type.h"
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#include "miscadmin.h"
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#include "optimizer/optimizer.h"
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#include "utils/sampling.h"
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#include "utils/spccache.h"
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PG_MODULE_MAGIC;
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PG_FUNCTION_INFO_V1(tsm_system_time_handler);
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/* Private state */
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typedef struct
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{
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uint32 seed; /* random seed */
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double millis; /* time limit for sampling */
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instr_time start_time; /* scan start time */
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OffsetNumber lt; /* last tuple returned from current block */
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BlockNumber doneblocks; /* number of already-scanned blocks */
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BlockNumber lb; /* last block visited */
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/* these three values are not changed during a rescan: */
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BlockNumber nblocks; /* number of blocks in relation */
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BlockNumber firstblock; /* first block to sample from */
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BlockNumber step; /* step size, or 0 if not set yet */
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} SystemTimeSamplerData;
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static void system_time_samplescangetsamplesize(PlannerInfo *root,
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RelOptInfo *baserel,
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List *paramexprs,
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BlockNumber *pages,
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double *tuples);
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static void system_time_initsamplescan(SampleScanState *node,
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int eflags);
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static void system_time_beginsamplescan(SampleScanState *node,
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Datum *params,
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int nparams,
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uint32 seed);
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static BlockNumber system_time_nextsampleblock(SampleScanState *node, BlockNumber nblocks);
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static OffsetNumber system_time_nextsampletuple(SampleScanState *node,
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BlockNumber blockno,
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OffsetNumber maxoffset);
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static uint32 random_relative_prime(uint32 n, pg_prng_state *randstate);
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/*
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* Create a TsmRoutine descriptor for the SYSTEM_TIME method.
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*/
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Datum
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tsm_system_time_handler(PG_FUNCTION_ARGS)
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{
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TsmRoutine *tsm = makeNode(TsmRoutine);
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tsm->parameterTypes = list_make1_oid(FLOAT8OID);
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/* See notes at head of file */
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tsm->repeatable_across_queries = false;
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tsm->repeatable_across_scans = false;
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tsm->SampleScanGetSampleSize = system_time_samplescangetsamplesize;
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tsm->InitSampleScan = system_time_initsamplescan;
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tsm->BeginSampleScan = system_time_beginsamplescan;
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tsm->NextSampleBlock = system_time_nextsampleblock;
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tsm->NextSampleTuple = system_time_nextsampletuple;
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tsm->EndSampleScan = NULL;
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PG_RETURN_POINTER(tsm);
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}
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/*
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* Sample size estimation.
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*/
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static void
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system_time_samplescangetsamplesize(PlannerInfo *root,
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RelOptInfo *baserel,
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List *paramexprs,
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BlockNumber *pages,
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double *tuples)
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{
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Node *limitnode;
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double millis;
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double spc_random_page_cost;
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double npages;
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double ntuples;
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/* Try to extract an estimate for the limit time spec */
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limitnode = (Node *) linitial(paramexprs);
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limitnode = estimate_expression_value(root, limitnode);
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if (IsA(limitnode, Const) &&
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!((Const *) limitnode)->constisnull)
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{
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millis = DatumGetFloat8(((Const *) limitnode)->constvalue);
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if (millis < 0 || isnan(millis))
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{
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/* Default millis if the value is bogus */
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millis = 1000;
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}
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}
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else
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{
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/* Default millis if we didn't obtain a non-null Const */
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millis = 1000;
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}
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/* Get the planner's idea of cost per page read */
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get_tablespace_page_costs(baserel->reltablespace,
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&spc_random_page_cost,
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NULL);
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/*
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* Estimate the number of pages we can read by assuming that the cost
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* figure is expressed in milliseconds. This is completely, unmistakably
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* bogus, but we have to do something to produce an estimate and there's
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* no better answer.
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*/
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if (spc_random_page_cost > 0)
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npages = millis / spc_random_page_cost;
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else
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npages = millis; /* even more bogus, but whatcha gonna do? */
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/* Clamp to sane value */
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npages = clamp_row_est(Min((double) baserel->pages, npages));
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if (baserel->tuples > 0 && baserel->pages > 0)
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{
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/* Estimate number of tuples returned based on tuple density */
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double density = baserel->tuples / (double) baserel->pages;
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ntuples = npages * density;
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}
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else
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{
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/* For lack of data, assume one tuple per page */
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ntuples = npages;
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}
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/* Clamp to the estimated relation size */
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ntuples = clamp_row_est(Min(baserel->tuples, ntuples));
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*pages = npages;
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*tuples = ntuples;
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}
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/*
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* Initialize during executor setup.
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*/
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static void
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system_time_initsamplescan(SampleScanState *node, int eflags)
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{
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node->tsm_state = palloc0(sizeof(SystemTimeSamplerData));
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/* Note the above leaves tsm_state->step equal to zero */
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}
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/*
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* Examine parameters and prepare for a sample scan.
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*/
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static void
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system_time_beginsamplescan(SampleScanState *node,
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Datum *params,
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int nparams,
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uint32 seed)
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{
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SystemTimeSamplerData *sampler = (SystemTimeSamplerData *) node->tsm_state;
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double millis = DatumGetFloat8(params[0]);
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if (millis < 0 || isnan(millis))
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ereport(ERROR,
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(errcode(ERRCODE_INVALID_TABLESAMPLE_ARGUMENT),
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errmsg("sample collection time must not be negative")));
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sampler->seed = seed;
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sampler->millis = millis;
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sampler->lt = InvalidOffsetNumber;
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sampler->doneblocks = 0;
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/* start_time, lb will be initialized during first NextSampleBlock call */
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/* we intentionally do not change nblocks/firstblock/step here */
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}
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/*
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* Select next block to sample.
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*
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* Uses linear probing algorithm for picking next block.
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*/
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static BlockNumber
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system_time_nextsampleblock(SampleScanState *node, BlockNumber nblocks)
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{
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SystemTimeSamplerData *sampler = (SystemTimeSamplerData *) node->tsm_state;
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instr_time cur_time;
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/* First call within scan? */
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if (sampler->doneblocks == 0)
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{
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/* First scan within query? */
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if (sampler->step == 0)
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{
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/* Initialize now that we have scan descriptor */
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pg_prng_state randstate;
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/* If relation is empty, there's nothing to scan */
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if (nblocks == 0)
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return InvalidBlockNumber;
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/* We only need an RNG during this setup step */
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sampler_random_init_state(sampler->seed, &randstate);
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/* Compute nblocks/firstblock/step only once per query */
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sampler->nblocks = nblocks;
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/* Choose random starting block within the relation */
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/* (Actually this is the predecessor of the first block visited) */
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sampler->firstblock = sampler_random_fract(&randstate) *
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sampler->nblocks;
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/* Find relative prime as step size for linear probing */
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sampler->step = random_relative_prime(sampler->nblocks, &randstate);
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}
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/* Reinitialize lb and start_time */
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sampler->lb = sampler->firstblock;
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INSTR_TIME_SET_CURRENT(sampler->start_time);
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}
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/* If we've read all blocks in relation, we're done */
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if (++sampler->doneblocks > sampler->nblocks)
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return InvalidBlockNumber;
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/* If we've used up all the allotted time, we're done */
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INSTR_TIME_SET_CURRENT(cur_time);
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INSTR_TIME_SUBTRACT(cur_time, sampler->start_time);
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if (INSTR_TIME_GET_MILLISEC(cur_time) >= sampler->millis)
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return InvalidBlockNumber;
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/*
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* It's probably impossible for scan->rs_nblocks to decrease between scans
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* within a query; but just in case, loop until we select a block number
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* less than scan->rs_nblocks. We don't care if scan->rs_nblocks has
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* increased since the first scan.
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*/
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do
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{
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/* Advance lb, using uint64 arithmetic to forestall overflow */
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sampler->lb = ((uint64) sampler->lb + sampler->step) % sampler->nblocks;
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} while (sampler->lb >= nblocks);
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return sampler->lb;
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}
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/*
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* Select next sampled tuple in current block.
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*
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* In block sampling, we just want to sample all the tuples in each selected
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* block.
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*
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* When we reach end of the block, return InvalidOffsetNumber which tells
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* SampleScan to go to next block.
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*/
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static OffsetNumber
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system_time_nextsampletuple(SampleScanState *node,
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BlockNumber blockno,
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OffsetNumber maxoffset)
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{
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SystemTimeSamplerData *sampler = (SystemTimeSamplerData *) node->tsm_state;
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OffsetNumber tupoffset = sampler->lt;
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/* Advance to next possible offset on page */
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if (tupoffset == InvalidOffsetNumber)
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tupoffset = FirstOffsetNumber;
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else
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tupoffset++;
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/* Done? */
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if (tupoffset > maxoffset)
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tupoffset = InvalidOffsetNumber;
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sampler->lt = tupoffset;
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return tupoffset;
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}
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/*
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* Compute greatest common divisor of two uint32's.
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*/
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static uint32
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gcd(uint32 a, uint32 b)
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{
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uint32 c;
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while (a != 0)
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{
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c = a;
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a = b % a;
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b = c;
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}
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return b;
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}
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/*
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* Pick a random value less than and relatively prime to n, if possible
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* (else return 1).
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*/
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static uint32
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random_relative_prime(uint32 n, pg_prng_state *randstate)
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{
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uint32 r;
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/* Safety check to avoid infinite loop or zero result for small n. */
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if (n <= 1)
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return 1;
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/*
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* This should only take 2 or 3 iterations as the probability of 2 numbers
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* being relatively prime is ~61%; but just in case, we'll include a
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* CHECK_FOR_INTERRUPTS in the loop.
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*/
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do
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{
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CHECK_FOR_INTERRUPTS();
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r = (uint32) (sampler_random_fract(randstate) * n);
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} while (r == 0 || gcd(r, n) > 1);
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return r;
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}
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