/*------------------------------------------------------------------------- * * gistutil.c * utilities routines for the postgres GiST index access method. * * * Portions Copyright (c) 1996-2019, PostgreSQL Global Development Group * Portions Copyright (c) 1994, Regents of the University of California * * IDENTIFICATION * src/backend/access/gist/gistutil.c *------------------------------------------------------------------------- */ #include "postgres.h" #include #include "access/gist_private.h" #include "access/htup_details.h" #include "access/reloptions.h" #include "catalog/pg_opclass.h" #include "storage/indexfsm.h" #include "storage/lmgr.h" #include "utils/float.h" #include "utils/syscache.h" #include "utils/snapmgr.h" #include "utils/lsyscache.h" /* * Write itup vector to page, has no control of free space. */ void gistfillbuffer(Page page, IndexTuple *itup, int len, OffsetNumber off) { OffsetNumber l = InvalidOffsetNumber; int i; if (off == InvalidOffsetNumber) off = (PageIsEmpty(page)) ? FirstOffsetNumber : OffsetNumberNext(PageGetMaxOffsetNumber(page)); for (i = 0; i < len; i++) { Size sz = IndexTupleSize(itup[i]); l = PageAddItem(page, (Item) itup[i], sz, off, false, false); if (l == InvalidOffsetNumber) elog(ERROR, "failed to add item to GiST index page, item %d out of %d, size %d bytes", i, len, (int) sz); off++; } } /* * Check space for itup vector on page */ bool gistnospace(Page page, IndexTuple *itvec, int len, OffsetNumber todelete, Size freespace) { unsigned int size = freespace, deleted = 0; int i; for (i = 0; i < len; i++) size += IndexTupleSize(itvec[i]) + sizeof(ItemIdData); if (todelete != InvalidOffsetNumber) { IndexTuple itup = (IndexTuple) PageGetItem(page, PageGetItemId(page, todelete)); deleted = IndexTupleSize(itup) + sizeof(ItemIdData); } return (PageGetFreeSpace(page) + deleted < size); } bool gistfitpage(IndexTuple *itvec, int len) { int i; Size size = 0; for (i = 0; i < len; i++) size += IndexTupleSize(itvec[i]) + sizeof(ItemIdData); /* TODO: Consider fillfactor */ return (size <= GiSTPageSize); } /* * Read buffer into itup vector */ IndexTuple * gistextractpage(Page page, int *len /* out */ ) { OffsetNumber i, maxoff; IndexTuple *itvec; maxoff = PageGetMaxOffsetNumber(page); *len = maxoff; itvec = palloc(sizeof(IndexTuple) * maxoff); for (i = FirstOffsetNumber; i <= maxoff; i = OffsetNumberNext(i)) itvec[i - FirstOffsetNumber] = (IndexTuple) PageGetItem(page, PageGetItemId(page, i)); return itvec; } /* * join two vectors into one */ IndexTuple * gistjoinvector(IndexTuple *itvec, int *len, IndexTuple *additvec, int addlen) { itvec = (IndexTuple *) repalloc((void *) itvec, sizeof(IndexTuple) * ((*len) + addlen)); memmove(&itvec[*len], additvec, sizeof(IndexTuple) * addlen); *len += addlen; return itvec; } /* * make plain IndexTupleVector */ IndexTupleData * gistfillitupvec(IndexTuple *vec, int veclen, int *memlen) { char *ptr, *ret; int i; *memlen = 0; for (i = 0; i < veclen; i++) *memlen += IndexTupleSize(vec[i]); ptr = ret = palloc(*memlen); for (i = 0; i < veclen; i++) { memcpy(ptr, vec[i], IndexTupleSize(vec[i])); ptr += IndexTupleSize(vec[i]); } return (IndexTupleData *) ret; } /* * Make unions of keys in IndexTuple vector (one union datum per index column). * Union Datums are returned into the attr/isnull arrays. * Resulting Datums aren't compressed. */ void gistMakeUnionItVec(GISTSTATE *giststate, IndexTuple *itvec, int len, Datum *attr, bool *isnull) { int i; GistEntryVector *evec; int attrsize; evec = (GistEntryVector *) palloc((len + 2) * sizeof(GISTENTRY) + GEVHDRSZ); for (i = 0; i < giststate->nonLeafTupdesc->natts; i++) { int j; /* Collect non-null datums for this column */ evec->n = 0; for (j = 0; j < len; j++) { Datum datum; bool IsNull; datum = index_getattr(itvec[j], i + 1, giststate->leafTupdesc, &IsNull); if (IsNull) continue; gistdentryinit(giststate, i, evec->vector + evec->n, datum, NULL, NULL, (OffsetNumber) 0, false, IsNull); evec->n++; } /* If this column was all NULLs, the union is NULL */ if (evec->n == 0) { attr[i] = (Datum) 0; isnull[i] = true; } else { if (evec->n == 1) { /* unionFn may expect at least two inputs */ evec->n = 2; evec->vector[1] = evec->vector[0]; } /* Make union and store in attr array */ attr[i] = FunctionCall2Coll(&giststate->unionFn[i], giststate->supportCollation[i], PointerGetDatum(evec), PointerGetDatum(&attrsize)); isnull[i] = false; } } } /* * Return an IndexTuple containing the result of applying the "union" * method to the specified IndexTuple vector. */ IndexTuple gistunion(Relation r, IndexTuple *itvec, int len, GISTSTATE *giststate) { Datum attr[INDEX_MAX_KEYS]; bool isnull[INDEX_MAX_KEYS]; gistMakeUnionItVec(giststate, itvec, len, attr, isnull); return gistFormTuple(giststate, r, attr, isnull, false); } /* * makes union of two key */ void gistMakeUnionKey(GISTSTATE *giststate, int attno, GISTENTRY *entry1, bool isnull1, GISTENTRY *entry2, bool isnull2, Datum *dst, bool *dstisnull) { /* we need a GistEntryVector with room for exactly 2 elements */ union { GistEntryVector gev; char padding[2 * sizeof(GISTENTRY) + GEVHDRSZ]; } storage; GistEntryVector *evec = &storage.gev; int dstsize; evec->n = 2; if (isnull1 && isnull2) { *dstisnull = true; *dst = (Datum) 0; } else { if (isnull1 == false && isnull2 == false) { evec->vector[0] = *entry1; evec->vector[1] = *entry2; } else if (isnull1 == false) { evec->vector[0] = *entry1; evec->vector[1] = *entry1; } else { evec->vector[0] = *entry2; evec->vector[1] = *entry2; } *dstisnull = false; *dst = FunctionCall2Coll(&giststate->unionFn[attno], giststate->supportCollation[attno], PointerGetDatum(evec), PointerGetDatum(&dstsize)); } } bool gistKeyIsEQ(GISTSTATE *giststate, int attno, Datum a, Datum b) { bool result; FunctionCall3Coll(&giststate->equalFn[attno], giststate->supportCollation[attno], a, b, PointerGetDatum(&result)); return result; } /* * Decompress all keys in tuple */ void gistDeCompressAtt(GISTSTATE *giststate, Relation r, IndexTuple tuple, Page p, OffsetNumber o, GISTENTRY *attdata, bool *isnull) { int i; for (i = 0; i < IndexRelationGetNumberOfKeyAttributes(r); i++) { Datum datum; datum = index_getattr(tuple, i + 1, giststate->leafTupdesc, &isnull[i]); gistdentryinit(giststate, i, &attdata[i], datum, r, p, o, false, isnull[i]); } } /* * Forms union of oldtup and addtup, if union == oldtup then return NULL */ IndexTuple gistgetadjusted(Relation r, IndexTuple oldtup, IndexTuple addtup, GISTSTATE *giststate) { bool neednew = false; GISTENTRY oldentries[INDEX_MAX_KEYS], addentries[INDEX_MAX_KEYS]; bool oldisnull[INDEX_MAX_KEYS], addisnull[INDEX_MAX_KEYS]; Datum attr[INDEX_MAX_KEYS]; bool isnull[INDEX_MAX_KEYS]; IndexTuple newtup = NULL; int i; gistDeCompressAtt(giststate, r, oldtup, NULL, (OffsetNumber) 0, oldentries, oldisnull); gistDeCompressAtt(giststate, r, addtup, NULL, (OffsetNumber) 0, addentries, addisnull); for (i = 0; i < IndexRelationGetNumberOfKeyAttributes(r); i++) { gistMakeUnionKey(giststate, i, oldentries + i, oldisnull[i], addentries + i, addisnull[i], attr + i, isnull + i); if (neednew) /* we already need new key, so we can skip check */ continue; if (isnull[i]) /* union of key may be NULL if and only if both keys are NULL */ continue; if (!addisnull[i]) { if (oldisnull[i] || !gistKeyIsEQ(giststate, i, oldentries[i].key, attr[i])) neednew = true; } } if (neednew) { /* need to update key */ newtup = gistFormTuple(giststate, r, attr, isnull, false); newtup->t_tid = oldtup->t_tid; } return newtup; } /* * Search an upper index page for the entry with lowest penalty for insertion * of the new index key contained in "it". * * Returns the index of the page entry to insert into. */ OffsetNumber gistchoose(Relation r, Page p, IndexTuple it, /* it has compressed entry */ GISTSTATE *giststate) { OffsetNumber result; OffsetNumber maxoff; OffsetNumber i; float best_penalty[INDEX_MAX_KEYS]; GISTENTRY entry, identry[INDEX_MAX_KEYS]; bool isnull[INDEX_MAX_KEYS]; int keep_current_best; Assert(!GistPageIsLeaf(p)); gistDeCompressAtt(giststate, r, it, NULL, (OffsetNumber) 0, identry, isnull); /* we'll return FirstOffsetNumber if page is empty (shouldn't happen) */ result = FirstOffsetNumber; /* * The index may have multiple columns, and there's a penalty value for * each column. The penalty associated with a column that appears earlier * in the index definition is strictly more important than the penalty of * a column that appears later in the index definition. * * best_penalty[j] is the best penalty we have seen so far for column j, * or -1 when we haven't yet examined column j. Array entries to the * right of the first -1 are undefined. */ best_penalty[0] = -1; /* * If we find a tuple that's exactly as good as the currently best one, we * could use either one. When inserting a lot of tuples with the same or * similar keys, it's preferable to descend down the same path when * possible, as that's more cache-friendly. On the other hand, if all * inserts land on the same leaf page after a split, we're never going to * insert anything to the other half of the split, and will end up using * only 50% of the available space. Distributing the inserts evenly would * lead to better space usage, but that hurts cache-locality during * insertion. To get the best of both worlds, when we find a tuple that's * exactly as good as the previous best, choose randomly whether to stick * to the old best, or use the new one. Once we decide to stick to the * old best, we keep sticking to it for any subsequent equally good tuples * we might find. This favors tuples with low offsets, but still allows * some inserts to go to other equally-good subtrees. * * keep_current_best is -1 if we haven't yet had to make a random choice * whether to keep the current best tuple. If we have done so, and * decided to keep it, keep_current_best is 1; if we've decided to * replace, keep_current_best is 0. (This state will be reset to -1 as * soon as we've made the replacement, but sometimes we make the choice in * advance of actually finding a replacement best tuple.) */ keep_current_best = -1; /* * Loop over tuples on page. */ maxoff = PageGetMaxOffsetNumber(p); Assert(maxoff >= FirstOffsetNumber); for (i = FirstOffsetNumber; i <= maxoff; i = OffsetNumberNext(i)) { IndexTuple itup = (IndexTuple) PageGetItem(p, PageGetItemId(p, i)); bool zero_penalty; int j; zero_penalty = true; /* Loop over index attributes. */ for (j = 0; j < IndexRelationGetNumberOfKeyAttributes(r); j++) { Datum datum; float usize; bool IsNull; /* Compute penalty for this column. */ datum = index_getattr(itup, j + 1, giststate->leafTupdesc, &IsNull); gistdentryinit(giststate, j, &entry, datum, r, p, i, false, IsNull); usize = gistpenalty(giststate, j, &entry, IsNull, &identry[j], isnull[j]); if (usize > 0) zero_penalty = false; if (best_penalty[j] < 0 || usize < best_penalty[j]) { /* * New best penalty for column. Tentatively select this tuple * as the target, and record the best penalty. Then reset the * next column's penalty to "unknown" (and indirectly, the * same for all the ones to its right). This will force us to * adopt this tuple's penalty values as the best for all the * remaining columns during subsequent loop iterations. */ result = i; best_penalty[j] = usize; if (j < IndexRelationGetNumberOfKeyAttributes(r) - 1) best_penalty[j + 1] = -1; /* we have new best, so reset keep-it decision */ keep_current_best = -1; } else if (best_penalty[j] == usize) { /* * The current tuple is exactly as good for this column as the * best tuple seen so far. The next iteration of this loop * will compare the next column. */ } else { /* * The current tuple is worse for this column than the best * tuple seen so far. Skip the remaining columns and move on * to the next tuple, if any. */ zero_penalty = false; /* so outer loop won't exit */ break; } } /* * If we looped past the last column, and did not update "result", * then this tuple is exactly as good as the prior best tuple. */ if (j == IndexRelationGetNumberOfKeyAttributes(r) && result != i) { if (keep_current_best == -1) { /* we didn't make the random choice yet for this old best */ keep_current_best = (random() <= (MAX_RANDOM_VALUE / 2)) ? 1 : 0; } if (keep_current_best == 0) { /* we choose to use the new tuple */ result = i; /* choose again if there are even more exactly-as-good ones */ keep_current_best = -1; } } /* * If we find a tuple with zero penalty for all columns, and we've * decided we don't want to search for another tuple with equal * penalty, there's no need to examine remaining tuples; just break * out of the loop and return it. */ if (zero_penalty) { if (keep_current_best == -1) { /* we didn't make the random choice yet for this old best */ keep_current_best = (random() <= (MAX_RANDOM_VALUE / 2)) ? 1 : 0; } if (keep_current_best == 1) break; } } return result; } /* * initialize a GiST entry with a decompressed version of key */ void gistdentryinit(GISTSTATE *giststate, int nkey, GISTENTRY *e, Datum k, Relation r, Page pg, OffsetNumber o, bool l, bool isNull) { if (!isNull) { GISTENTRY *dep; gistentryinit(*e, k, r, pg, o, l); /* there may not be a decompress function in opclass */ if (!OidIsValid(giststate->decompressFn[nkey].fn_oid)) return; dep = (GISTENTRY *) DatumGetPointer(FunctionCall1Coll(&giststate->decompressFn[nkey], giststate->supportCollation[nkey], PointerGetDatum(e))); /* decompressFn may just return the given pointer */ if (dep != e) gistentryinit(*e, dep->key, dep->rel, dep->page, dep->offset, dep->leafkey); } else gistentryinit(*e, (Datum) 0, r, pg, o, l); } IndexTuple gistFormTuple(GISTSTATE *giststate, Relation r, Datum attdata[], bool isnull[], bool isleaf) { Datum compatt[INDEX_MAX_KEYS]; int i; IndexTuple res; /* * Call the compress method on each attribute. */ for (i = 0; i < IndexRelationGetNumberOfKeyAttributes(r); i++) { if (isnull[i]) compatt[i] = (Datum) 0; else { GISTENTRY centry; GISTENTRY *cep; gistentryinit(centry, attdata[i], r, NULL, (OffsetNumber) 0, isleaf); /* there may not be a compress function in opclass */ if (OidIsValid(giststate->compressFn[i].fn_oid)) cep = (GISTENTRY *) DatumGetPointer(FunctionCall1Coll(&giststate->compressFn[i], giststate->supportCollation[i], PointerGetDatum(¢ry))); else cep = ¢ry; compatt[i] = cep->key; } } if (isleaf) { /* * Emplace each included attribute if any. */ for (; i < r->rd_att->natts; i++) { if (isnull[i]) compatt[i] = (Datum) 0; else compatt[i] = attdata[i]; } } res = index_form_tuple(isleaf ? giststate->leafTupdesc : giststate->nonLeafTupdesc, compatt, isnull); /* * The offset number on tuples on internal pages is unused. For historical * reasons, it is set to 0xffff. */ ItemPointerSetOffsetNumber(&(res->t_tid), 0xffff); return res; } /* * initialize a GiST entry with fetched value in key field */ static Datum gistFetchAtt(GISTSTATE *giststate, int nkey, Datum k, Relation r) { GISTENTRY fentry; GISTENTRY *fep; gistentryinit(fentry, k, r, NULL, (OffsetNumber) 0, false); fep = (GISTENTRY *) DatumGetPointer(FunctionCall1Coll(&giststate->fetchFn[nkey], giststate->supportCollation[nkey], PointerGetDatum(&fentry))); /* fetchFn set 'key', return it to the caller */ return fep->key; } /* * Fetch all keys in tuple. * Returns a new HeapTuple containing the originally-indexed data. */ HeapTuple gistFetchTuple(GISTSTATE *giststate, Relation r, IndexTuple tuple) { MemoryContext oldcxt = MemoryContextSwitchTo(giststate->tempCxt); Datum fetchatt[INDEX_MAX_KEYS]; bool isnull[INDEX_MAX_KEYS]; int i; for (i = 0; i < IndexRelationGetNumberOfKeyAttributes(r); i++) { Datum datum; datum = index_getattr(tuple, i + 1, giststate->leafTupdesc, &isnull[i]); if (giststate->fetchFn[i].fn_oid != InvalidOid) { if (!isnull[i]) fetchatt[i] = gistFetchAtt(giststate, i, datum, r); else fetchatt[i] = (Datum) 0; } else if (giststate->compressFn[i].fn_oid == InvalidOid) { /* * If opclass does not provide compress method that could change * original value, att is necessarily stored in original form. */ if (!isnull[i]) fetchatt[i] = datum; else fetchatt[i] = (Datum) 0; } else { /* * Index-only scans not supported for this column. Since the * planner chose an index-only scan anyway, it is not interested * in this column, and we can replace it with a NULL. */ isnull[i] = true; fetchatt[i] = (Datum) 0; } } /* * Get each included attribute. */ for (; i < r->rd_att->natts; i++) { fetchatt[i] = index_getattr(tuple, i + 1, giststate->leafTupdesc, &isnull[i]); } MemoryContextSwitchTo(oldcxt); return heap_form_tuple(giststate->fetchTupdesc, fetchatt, isnull); } float gistpenalty(GISTSTATE *giststate, int attno, GISTENTRY *orig, bool isNullOrig, GISTENTRY *add, bool isNullAdd) { float penalty = 0.0; if (giststate->penaltyFn[attno].fn_strict == false || (isNullOrig == false && isNullAdd == false)) { FunctionCall3Coll(&giststate->penaltyFn[attno], giststate->supportCollation[attno], PointerGetDatum(orig), PointerGetDatum(add), PointerGetDatum(&penalty)); /* disallow negative or NaN penalty */ if (isnan(penalty) || penalty < 0.0) penalty = 0.0; } else if (isNullOrig && isNullAdd) penalty = 0.0; else { /* try to prevent mixing null and non-null values */ penalty = get_float4_infinity(); } return penalty; } /* * Initialize a new index page */ void GISTInitBuffer(Buffer b, uint32 f) { GISTPageOpaque opaque; Page page; Size pageSize; pageSize = BufferGetPageSize(b); page = BufferGetPage(b); PageInit(page, pageSize, sizeof(GISTPageOpaqueData)); opaque = GistPageGetOpaque(page); /* page was already zeroed by PageInit, so this is not needed: */ /* memset(&(opaque->nsn), 0, sizeof(GistNSN)); */ opaque->rightlink = InvalidBlockNumber; opaque->flags = f; opaque->gist_page_id = GIST_PAGE_ID; } /* * Verify that a freshly-read page looks sane. */ void gistcheckpage(Relation rel, Buffer buf) { Page page = BufferGetPage(buf); /* * ReadBuffer verifies that every newly-read page passes * PageHeaderIsValid, which means it either contains a reasonably sane * page header or is all-zero. We have to defend against the all-zero * case, however. */ if (PageIsNew(page)) ereport(ERROR, (errcode(ERRCODE_INDEX_CORRUPTED), errmsg("index \"%s\" contains unexpected zero page at block %u", RelationGetRelationName(rel), BufferGetBlockNumber(buf)), errhint("Please REINDEX it."))); /* * Additionally check that the special area looks sane. */ if (PageGetSpecialSize(page) != MAXALIGN(sizeof(GISTPageOpaqueData))) ereport(ERROR, (errcode(ERRCODE_INDEX_CORRUPTED), errmsg("index \"%s\" contains corrupted page at block %u", RelationGetRelationName(rel), BufferGetBlockNumber(buf)), errhint("Please REINDEX it."))); } /* * Allocate a new page (either by recycling, or by extending the index file) * * The returned buffer is already pinned and exclusive-locked * * Caller is responsible for initializing the page by calling GISTInitBuffer */ Buffer gistNewBuffer(Relation r) { Buffer buffer; bool needLock; /* First, try to get a page from FSM */ for (;;) { BlockNumber blkno = GetFreeIndexPage(r); if (blkno == InvalidBlockNumber) break; /* nothing left in FSM */ buffer = ReadBuffer(r, blkno); /* * We have to guard against the possibility that someone else already * recycled this page; the buffer may be locked if so. */ if (ConditionalLockBuffer(buffer)) { Page page = BufferGetPage(buffer); /* * If the page was never initialized, it's OK to use. */ if (PageIsNew(page)) return buffer; gistcheckpage(r, buffer); /* * Otherwise, recycle it if deleted, and too old to have any processes * interested in it. */ if (gistPageRecyclable(page)) { /* * If we are generating WAL for Hot Standby then create a * WAL record that will allow us to conflict with queries * running on standby, in case they have snapshots older * than the page's deleteXid. */ if (XLogStandbyInfoActive() && RelationNeedsWAL(r)) gistXLogPageReuse(r, blkno, GistPageGetDeleteXid(page)); return buffer; } LockBuffer(buffer, GIST_UNLOCK); } /* Can't use it, so release buffer and try again */ ReleaseBuffer(buffer); } /* Must extend the file */ needLock = !RELATION_IS_LOCAL(r); if (needLock) LockRelationForExtension(r, ExclusiveLock); buffer = ReadBuffer(r, P_NEW); LockBuffer(buffer, GIST_EXCLUSIVE); if (needLock) UnlockRelationForExtension(r, ExclusiveLock); return buffer; } /* Can this page be recycled yet? */ bool gistPageRecyclable(Page page) { return PageIsNew(page) || (GistPageIsDeleted(page) && TransactionIdPrecedes(GistPageGetDeleteXid(page), RecentGlobalXmin)); } bytea * gistoptions(Datum reloptions, bool validate) { relopt_value *options; GiSTOptions *rdopts; int numoptions; static const relopt_parse_elt tab[] = { {"fillfactor", RELOPT_TYPE_INT, offsetof(GiSTOptions, fillfactor)}, {"buffering", RELOPT_TYPE_STRING, offsetof(GiSTOptions, bufferingModeOffset)} }; options = parseRelOptions(reloptions, validate, RELOPT_KIND_GIST, &numoptions); /* if none set, we're done */ if (numoptions == 0) return NULL; rdopts = allocateReloptStruct(sizeof(GiSTOptions), options, numoptions); fillRelOptions((void *) rdopts, sizeof(GiSTOptions), options, numoptions, validate, tab, lengthof(tab)); pfree(options); return (bytea *) rdopts; } /* * gistproperty() -- Check boolean properties of indexes. * * This is optional for most AMs, but is required for GiST because the core * property code doesn't support AMPROP_DISTANCE_ORDERABLE. We also handle * AMPROP_RETURNABLE here to save opening the rel to call gistcanreturn. */ bool gistproperty(Oid index_oid, int attno, IndexAMProperty prop, const char *propname, bool *res, bool *isnull) { Oid opclass, opfamily, opcintype; int16 procno; /* Only answer column-level inquiries */ if (attno == 0) return false; /* * Currently, GiST distance-ordered scans require that there be a distance * function in the opclass with the default types (i.e. the one loaded * into the relcache entry, see initGISTstate). So we assume that if such * a function exists, then there's a reason for it (rather than grubbing * through all the opfamily's operators to find an ordered one). * * Essentially the same code can test whether we support returning the * column data, since that's true if the opclass provides a fetch proc. */ switch (prop) { case AMPROP_DISTANCE_ORDERABLE: procno = GIST_DISTANCE_PROC; break; case AMPROP_RETURNABLE: procno = GIST_FETCH_PROC; break; default: return false; } /* First we need to know the column's opclass. */ opclass = get_index_column_opclass(index_oid, attno); if (!OidIsValid(opclass)) { *isnull = true; return true; } /* Now look up the opclass family and input datatype. */ if (!get_opclass_opfamily_and_input_type(opclass, &opfamily, &opcintype)) { *isnull = true; return true; } /* And now we can check whether the function is provided. */ *res = SearchSysCacheExists4(AMPROCNUM, ObjectIdGetDatum(opfamily), ObjectIdGetDatum(opcintype), ObjectIdGetDatum(opcintype), Int16GetDatum(procno)); /* * Special case: even without a fetch function, AMPROP_RETURNABLE is true * if the opclass has no compress function. */ if (prop == AMPROP_RETURNABLE && !*res) { *res = !SearchSysCacheExists4(AMPROCNUM, ObjectIdGetDatum(opfamily), ObjectIdGetDatum(opcintype), ObjectIdGetDatum(opcintype), Int16GetDatum(GIST_COMPRESS_PROC)); } *isnull = false; return true; } /* * Temporary and unlogged GiST indexes are not WAL-logged, but we need LSNs * to detect concurrent page splits anyway. This function provides a fake * sequence of LSNs for that purpose. */ XLogRecPtr gistGetFakeLSN(Relation rel) { static XLogRecPtr counter = FirstNormalUnloggedLSN; if (rel->rd_rel->relpersistence == RELPERSISTENCE_TEMP) { /* * Temporary relations are only accessible in our session, so a simple * backend-local counter will do. */ return counter++; } else { /* * Unlogged relations are accessible from other backends, and survive * (clean) restarts. GetFakeLSNForUnloggedRel() handles that for us. */ Assert(rel->rd_rel->relpersistence == RELPERSISTENCE_UNLOGGED); return GetFakeLSNForUnloggedRel(); } }