/*------------------------------------------------------------------------- * * tsm_system_rows.c * support routines for SYSTEM_ROWS tablesample method * * The desire here is to produce a random sample with a given number of rows * (or the whole relation, if that is fewer rows). We use a block-sampling * approach. To ensure that the whole relation will be visited if necessary, * we start at a randomly chosen block and then advance with a stride that * is randomly chosen but is relatively prime to the relation's nblocks. * * Because of the dependence on nblocks, this method cannot be repeatable * across queries. (Even if the user hasn't explicitly changed the relation, * maintenance activities such as autovacuum might change nblocks.) However, * we can at least make it repeatable across scans, by determining the * sampling pattern only once on the first scan. This means that rescans * won't visit blocks added after the first scan, but that is fine since * such blocks shouldn't contain any visible tuples anyway. * * Portions Copyright (c) 1996-2019, PostgreSQL Global Development Group * Portions Copyright (c) 1994, Regents of the University of California * * IDENTIFICATION * contrib/tsm_system_rows/tsm_system_rows.c * *------------------------------------------------------------------------- */ #include "postgres.h" #include "access/relscan.h" #include "access/tsmapi.h" #include "catalog/pg_type.h" #include "miscadmin.h" #include "optimizer/clauses.h" #include "optimizer/cost.h" #include "utils/sampling.h" PG_MODULE_MAGIC; PG_FUNCTION_INFO_V1(tsm_system_rows_handler); /* Private state */ typedef struct { uint32 seed; /* random seed */ int64 ntuples; /* number of tuples to return */ int64 donetuples; /* number of tuples already returned */ OffsetNumber lt; /* last tuple returned from current block */ BlockNumber doneblocks; /* number of already-scanned blocks */ BlockNumber lb; /* last block visited */ /* these three values are not changed during a rescan: */ BlockNumber nblocks; /* number of blocks in relation */ BlockNumber firstblock; /* first block to sample from */ BlockNumber step; /* step size, or 0 if not set yet */ } SystemRowsSamplerData; static void system_rows_samplescangetsamplesize(PlannerInfo *root, RelOptInfo *baserel, List *paramexprs, BlockNumber *pages, double *tuples); static void system_rows_initsamplescan(SampleScanState *node, int eflags); static void system_rows_beginsamplescan(SampleScanState *node, Datum *params, int nparams, uint32 seed); static BlockNumber system_rows_nextsampleblock(SampleScanState *node); static OffsetNumber system_rows_nextsampletuple(SampleScanState *node, BlockNumber blockno, OffsetNumber maxoffset); static bool SampleOffsetVisible(OffsetNumber tupoffset, HeapScanDesc scan); static uint32 random_relative_prime(uint32 n, SamplerRandomState randstate); /* * Create a TsmRoutine descriptor for the SYSTEM_ROWS method. */ Datum tsm_system_rows_handler(PG_FUNCTION_ARGS) { TsmRoutine *tsm = makeNode(TsmRoutine); tsm->parameterTypes = list_make1_oid(INT8OID); /* See notes at head of file */ tsm->repeatable_across_queries = false; tsm->repeatable_across_scans = true; tsm->SampleScanGetSampleSize = system_rows_samplescangetsamplesize; tsm->InitSampleScan = system_rows_initsamplescan; tsm->BeginSampleScan = system_rows_beginsamplescan; tsm->NextSampleBlock = system_rows_nextsampleblock; tsm->NextSampleTuple = system_rows_nextsampletuple; tsm->EndSampleScan = NULL; PG_RETURN_POINTER(tsm); } /* * Sample size estimation. */ static void system_rows_samplescangetsamplesize(PlannerInfo *root, RelOptInfo *baserel, List *paramexprs, BlockNumber *pages, double *tuples) { Node *limitnode; int64 ntuples; double npages; /* Try to extract an estimate for the limit rowcount */ limitnode = (Node *) linitial(paramexprs); limitnode = estimate_expression_value(root, limitnode); if (IsA(limitnode, Const) && !((Const *) limitnode)->constisnull) { ntuples = DatumGetInt64(((Const *) limitnode)->constvalue); if (ntuples < 0) { /* Default ntuples if the value is bogus */ ntuples = 1000; } } else { /* Default ntuples if we didn't obtain a non-null Const */ ntuples = 1000; } /* Clamp to the estimated relation size */ if (ntuples > baserel->tuples) ntuples = (int64) baserel->tuples; ntuples = clamp_row_est(ntuples); if (baserel->tuples > 0 && baserel->pages > 0) { /* Estimate number of pages visited based on tuple density */ double density = baserel->tuples / (double) baserel->pages; npages = ntuples / density; } else { /* For lack of data, assume one tuple per page */ npages = ntuples; } /* Clamp to sane value */ npages = clamp_row_est(Min((double) baserel->pages, npages)); *pages = npages; *tuples = ntuples; } /* * Initialize during executor setup. */ static void system_rows_initsamplescan(SampleScanState *node, int eflags) { node->tsm_state = palloc0(sizeof(SystemRowsSamplerData)); /* Note the above leaves tsm_state->step equal to zero */ } /* * Examine parameters and prepare for a sample scan. */ static void system_rows_beginsamplescan(SampleScanState *node, Datum *params, int nparams, uint32 seed) { SystemRowsSamplerData *sampler = (SystemRowsSamplerData *) node->tsm_state; int64 ntuples = DatumGetInt64(params[0]); if (ntuples < 0) ereport(ERROR, (errcode(ERRCODE_INVALID_TABLESAMPLE_ARGUMENT), errmsg("sample size must not be negative"))); sampler->seed = seed; sampler->ntuples = ntuples; sampler->donetuples = 0; sampler->lt = InvalidOffsetNumber; sampler->doneblocks = 0; /* lb will be initialized during first NextSampleBlock call */ /* we intentionally do not change nblocks/firstblock/step here */ /* * We *must* use pagemode visibility checking in this module, so force * that even though it's currently default. */ node->use_pagemode = true; } /* * Select next block to sample. * * Uses linear probing algorithm for picking next block. */ static BlockNumber system_rows_nextsampleblock(SampleScanState *node) { SystemRowsSamplerData *sampler = (SystemRowsSamplerData *) node->tsm_state; HeapScanDesc scan = node->ss.ss_currentScanDesc; /* First call within scan? */ if (sampler->doneblocks == 0) { /* First scan within query? */ if (sampler->step == 0) { /* Initialize now that we have scan descriptor */ SamplerRandomState randstate; /* If relation is empty, there's nothing to scan */ if (scan->rs_nblocks == 0) return InvalidBlockNumber; /* We only need an RNG during this setup step */ sampler_random_init_state(sampler->seed, randstate); /* Compute nblocks/firstblock/step only once per query */ sampler->nblocks = scan->rs_nblocks; /* Choose random starting block within the relation */ /* (Actually this is the predecessor of the first block visited) */ sampler->firstblock = sampler_random_fract(randstate) * sampler->nblocks; /* Find relative prime as step size for linear probing */ sampler->step = random_relative_prime(sampler->nblocks, randstate); } /* Reinitialize lb */ sampler->lb = sampler->firstblock; } /* If we've read all blocks or returned all needed tuples, we're done */ if (++sampler->doneblocks > sampler->nblocks || sampler->donetuples >= sampler->ntuples) return InvalidBlockNumber; /* * It's probably impossible for scan->rs_nblocks to decrease between scans * within a query; but just in case, loop until we select a block number * less than scan->rs_nblocks. We don't care if scan->rs_nblocks has * increased since the first scan. */ do { /* Advance lb, using uint64 arithmetic to forestall overflow */ sampler->lb = ((uint64) sampler->lb + sampler->step) % sampler->nblocks; } while (sampler->lb >= scan->rs_nblocks); return sampler->lb; } /* * Select next sampled tuple in current block. * * In block sampling, we just want to sample all the tuples in each selected * block. * * When we reach end of the block, return InvalidOffsetNumber which tells * SampleScan to go to next block. */ static OffsetNumber system_rows_nextsampletuple(SampleScanState *node, BlockNumber blockno, OffsetNumber maxoffset) { SystemRowsSamplerData *sampler = (SystemRowsSamplerData *) node->tsm_state; HeapScanDesc scan = node->ss.ss_currentScanDesc; OffsetNumber tupoffset = sampler->lt; /* Quit if we've returned all needed tuples */ if (sampler->donetuples >= sampler->ntuples) return InvalidOffsetNumber; /* * Because we should only count visible tuples as being returned, we need * to search for a visible tuple rather than just let the core code do it. */ /* We rely on the data accumulated in pagemode access */ Assert(scan->rs_pageatatime); for (;;) { /* Advance to next possible offset on page */ if (tupoffset == InvalidOffsetNumber) tupoffset = FirstOffsetNumber; else tupoffset++; /* Done? */ if (tupoffset > maxoffset) { tupoffset = InvalidOffsetNumber; break; } /* Found a candidate? */ if (SampleOffsetVisible(tupoffset, scan)) { sampler->donetuples++; break; } } sampler->lt = tupoffset; return tupoffset; } /* * Check if tuple offset is visible * * In pageatatime mode, heapgetpage() already did visibility checks, * so just look at the info it left in rs_vistuples[]. */ static bool SampleOffsetVisible(OffsetNumber tupoffset, HeapScanDesc scan) { int start = 0, end = scan->rs_ntuples - 1; while (start <= end) { int mid = (start + end) / 2; OffsetNumber curoffset = scan->rs_vistuples[mid]; if (tupoffset == curoffset) return true; else if (tupoffset < curoffset) end = mid - 1; else start = mid + 1; } return false; } /* * Compute greatest common divisor of two uint32's. */ static uint32 gcd(uint32 a, uint32 b) { uint32 c; while (a != 0) { c = a; a = b % a; b = c; } return b; } /* * Pick a random value less than and relatively prime to n, if possible * (else return 1). */ static uint32 random_relative_prime(uint32 n, SamplerRandomState randstate) { uint32 r; /* Safety check to avoid infinite loop or zero result for small n. */ if (n <= 1) return 1; /* * This should only take 2 or 3 iterations as the probability of 2 numbers * being relatively prime is ~61%; but just in case, we'll include a * CHECK_FOR_INTERRUPTS in the loop. */ do { CHECK_FOR_INTERRUPTS(); r = (uint32) (sampler_random_fract(randstate) * n); } while (r == 0 || gcd(r, n) > 1); return r; }