/*------------------------------------------------------------------------- * * spgtextproc.c * implementation of radix tree (compressed trie) over text * * In a text_ops SPGiST index, inner tuples can have a prefix which is the * common prefix of all strings indexed under that tuple. The node labels * represent the next byte of the string(s) after the prefix. Assuming we * always use the longest possible prefix, we will get more than one node * label unless the prefix length is restricted by SPGIST_MAX_PREFIX_LENGTH. * * To reconstruct the indexed string for any index entry, concatenate the * inner-tuple prefixes and node labels starting at the root and working * down to the leaf entry, then append the datum in the leaf entry. * (While descending the tree, "level" is the number of bytes reconstructed * so far.) * * However, there are two special cases for node labels: -1 indicates that * there are no more bytes after the prefix-so-far, and -2 indicates that we * had to split an existing allTheSame tuple (in such a case we have to create * a node label that doesn't correspond to any string byte). In either case, * the node label does not contribute anything to the reconstructed string. * * Previously, we used a node label of zero for both special cases, but * this was problematic because one can't tell whether a string ending at * the current level can be pushed down into such a child node. For * backwards compatibility, we still support such node labels for reading; * but no new entries will ever be pushed down into a zero-labeled child. * No new entries ever get pushed into a -2-labeled child, either. * * * Portions Copyright (c) 1996-2024, PostgreSQL Global Development Group * Portions Copyright (c) 1994, Regents of the University of California * * IDENTIFICATION * src/backend/access/spgist/spgtextproc.c * *------------------------------------------------------------------------- */ #include "postgres.h" #include "access/spgist.h" #include "catalog/pg_type.h" #include "common/int.h" #include "mb/pg_wchar.h" #include "utils/datum.h" #include "utils/fmgrprotos.h" #include "utils/pg_locale.h" #include "utils/varlena.h" #include "varatt.h" /* * In the worst case, an inner tuple in a text radix tree could have as many * as 258 nodes (one for each possible byte value, plus the two special * cases). Each node can take 16 bytes on MAXALIGN=8 machines. The inner * tuple must fit on an index page of size BLCKSZ. Rather than assuming we * know the exact amount of overhead imposed by page headers, tuple headers, * etc, we leave 100 bytes for that (the actual overhead should be no more * than 56 bytes at this writing, so there is slop in this number). * So we can safely create prefixes up to BLCKSZ - 258 * 16 - 100 bytes long. * Unfortunately, because 258 * 16 is over 4K, there is no safe prefix length * when BLCKSZ is less than 8K; it is always possible to get "SPGiST inner * tuple size exceeds maximum" if there are too many distinct next-byte values * at a given place in the tree. Since use of nonstandard block sizes appears * to be negligible in the field, we just live with that fact for now, * choosing a max prefix size of 32 bytes when BLCKSZ is configured smaller * than default. */ #define SPGIST_MAX_PREFIX_LENGTH Max((int) (BLCKSZ - 258 * 16 - 100), 32) /* * Strategy for collation aware operator on text is equal to btree strategy * plus value of 10. * * Current collation aware strategies and their corresponding btree strategies: * 11 BTLessStrategyNumber * 12 BTLessEqualStrategyNumber * 14 BTGreaterEqualStrategyNumber * 15 BTGreaterStrategyNumber */ #define SPG_STRATEGY_ADDITION (10) #define SPG_IS_COLLATION_AWARE_STRATEGY(s) ((s) > SPG_STRATEGY_ADDITION \ && (s) != RTPrefixStrategyNumber) /* Struct for sorting values in picksplit */ typedef struct spgNodePtr { Datum d; int i; int16 c; } spgNodePtr; Datum spg_text_config(PG_FUNCTION_ARGS) { /* spgConfigIn *cfgin = (spgConfigIn *) PG_GETARG_POINTER(0); */ spgConfigOut *cfg = (spgConfigOut *) PG_GETARG_POINTER(1); cfg->prefixType = TEXTOID; cfg->labelType = INT2OID; cfg->canReturnData = true; cfg->longValuesOK = true; /* suffixing will shorten long values */ PG_RETURN_VOID(); } /* * Form a text datum from the given not-necessarily-null-terminated string, * using short varlena header format if possible */ static Datum formTextDatum(const char *data, int datalen) { char *p; p = (char *) palloc(datalen + VARHDRSZ); if (datalen + VARHDRSZ_SHORT <= VARATT_SHORT_MAX) { SET_VARSIZE_SHORT(p, datalen + VARHDRSZ_SHORT); if (datalen) memcpy(p + VARHDRSZ_SHORT, data, datalen); } else { SET_VARSIZE(p, datalen + VARHDRSZ); memcpy(p + VARHDRSZ, data, datalen); } return PointerGetDatum(p); } /* * Find the length of the common prefix of a and b */ static int commonPrefix(const char *a, const char *b, int lena, int lenb) { int i = 0; while (i < lena && i < lenb && *a == *b) { a++; b++; i++; } return i; } /* * Binary search an array of int16 datums for a match to c * * On success, *i gets the match location; on failure, it gets where to insert */ static bool searchChar(Datum *nodeLabels, int nNodes, int16 c, int *i) { int StopLow = 0, StopHigh = nNodes; while (StopLow < StopHigh) { int StopMiddle = (StopLow + StopHigh) >> 1; int16 middle = DatumGetInt16(nodeLabels[StopMiddle]); if (c < middle) StopHigh = StopMiddle; else if (c > middle) StopLow = StopMiddle + 1; else { *i = StopMiddle; return true; } } *i = StopHigh; return false; } Datum spg_text_choose(PG_FUNCTION_ARGS) { spgChooseIn *in = (spgChooseIn *) PG_GETARG_POINTER(0); spgChooseOut *out = (spgChooseOut *) PG_GETARG_POINTER(1); text *inText = DatumGetTextPP(in->datum); char *inStr = VARDATA_ANY(inText); int inSize = VARSIZE_ANY_EXHDR(inText); char *prefixStr = NULL; int prefixSize = 0; int commonLen = 0; int16 nodeChar = 0; int i = 0; /* Check for prefix match, set nodeChar to first byte after prefix */ if (in->hasPrefix) { text *prefixText = DatumGetTextPP(in->prefixDatum); prefixStr = VARDATA_ANY(prefixText); prefixSize = VARSIZE_ANY_EXHDR(prefixText); commonLen = commonPrefix(inStr + in->level, prefixStr, inSize - in->level, prefixSize); if (commonLen == prefixSize) { if (inSize - in->level > commonLen) nodeChar = *(unsigned char *) (inStr + in->level + commonLen); else nodeChar = -1; } else { /* Must split tuple because incoming value doesn't match prefix */ out->resultType = spgSplitTuple; if (commonLen == 0) { out->result.splitTuple.prefixHasPrefix = false; } else { out->result.splitTuple.prefixHasPrefix = true; out->result.splitTuple.prefixPrefixDatum = formTextDatum(prefixStr, commonLen); } out->result.splitTuple.prefixNNodes = 1; out->result.splitTuple.prefixNodeLabels = (Datum *) palloc(sizeof(Datum)); out->result.splitTuple.prefixNodeLabels[0] = Int16GetDatum(*(unsigned char *) (prefixStr + commonLen)); out->result.splitTuple.childNodeN = 0; if (prefixSize - commonLen == 1) { out->result.splitTuple.postfixHasPrefix = false; } else { out->result.splitTuple.postfixHasPrefix = true; out->result.splitTuple.postfixPrefixDatum = formTextDatum(prefixStr + commonLen + 1, prefixSize - commonLen - 1); } PG_RETURN_VOID(); } } else if (inSize > in->level) { nodeChar = *(unsigned char *) (inStr + in->level); } else { nodeChar = -1; } /* Look up nodeChar in the node label array */ if (searchChar(in->nodeLabels, in->nNodes, nodeChar, &i)) { /* * Descend to existing node. (If in->allTheSame, the core code will * ignore our nodeN specification here, but that's OK. We still have * to provide the correct levelAdd and restDatum values, and those are * the same regardless of which node gets chosen by core.) */ int levelAdd; out->resultType = spgMatchNode; out->result.matchNode.nodeN = i; levelAdd = commonLen; if (nodeChar >= 0) levelAdd++; out->result.matchNode.levelAdd = levelAdd; if (inSize - in->level - levelAdd > 0) out->result.matchNode.restDatum = formTextDatum(inStr + in->level + levelAdd, inSize - in->level - levelAdd); else out->result.matchNode.restDatum = formTextDatum(NULL, 0); } else if (in->allTheSame) { /* * Can't use AddNode action, so split the tuple. The upper tuple has * the same prefix as before and uses a dummy node label -2 for the * lower tuple. The lower tuple has no prefix and the same node * labels as the original tuple. * * Note: it might seem tempting to shorten the upper tuple's prefix, * if it has one, then use its last byte as label for the lower tuple. * But that doesn't win since we know the incoming value matches the * whole prefix: we'd just end up splitting the lower tuple again. */ out->resultType = spgSplitTuple; out->result.splitTuple.prefixHasPrefix = in->hasPrefix; out->result.splitTuple.prefixPrefixDatum = in->prefixDatum; out->result.splitTuple.prefixNNodes = 1; out->result.splitTuple.prefixNodeLabels = (Datum *) palloc(sizeof(Datum)); out->result.splitTuple.prefixNodeLabels[0] = Int16GetDatum(-2); out->result.splitTuple.childNodeN = 0; out->result.splitTuple.postfixHasPrefix = false; } else { /* Add a node for the not-previously-seen nodeChar value */ out->resultType = spgAddNode; out->result.addNode.nodeLabel = Int16GetDatum(nodeChar); out->result.addNode.nodeN = i; } PG_RETURN_VOID(); } /* qsort comparator to sort spgNodePtr structs by "c" */ static int cmpNodePtr(const void *a, const void *b) { const spgNodePtr *aa = (const spgNodePtr *) a; const spgNodePtr *bb = (const spgNodePtr *) b; return pg_cmp_s16(aa->c, bb->c); } Datum spg_text_picksplit(PG_FUNCTION_ARGS) { spgPickSplitIn *in = (spgPickSplitIn *) PG_GETARG_POINTER(0); spgPickSplitOut *out = (spgPickSplitOut *) PG_GETARG_POINTER(1); text *text0 = DatumGetTextPP(in->datums[0]); int i, commonLen; spgNodePtr *nodes; /* Identify longest common prefix, if any */ commonLen = VARSIZE_ANY_EXHDR(text0); for (i = 1; i < in->nTuples && commonLen > 0; i++) { text *texti = DatumGetTextPP(in->datums[i]); int tmp = commonPrefix(VARDATA_ANY(text0), VARDATA_ANY(texti), VARSIZE_ANY_EXHDR(text0), VARSIZE_ANY_EXHDR(texti)); if (tmp < commonLen) commonLen = tmp; } /* * Limit the prefix length, if necessary, to ensure that the resulting * inner tuple will fit on a page. */ commonLen = Min(commonLen, SPGIST_MAX_PREFIX_LENGTH); /* Set node prefix to be that string, if it's not empty */ if (commonLen == 0) { out->hasPrefix = false; } else { out->hasPrefix = true; out->prefixDatum = formTextDatum(VARDATA_ANY(text0), commonLen); } /* Extract the node label (first non-common byte) from each value */ nodes = (spgNodePtr *) palloc(sizeof(spgNodePtr) * in->nTuples); for (i = 0; i < in->nTuples; i++) { text *texti = DatumGetTextPP(in->datums[i]); if (commonLen < VARSIZE_ANY_EXHDR(texti)) nodes[i].c = *(unsigned char *) (VARDATA_ANY(texti) + commonLen); else nodes[i].c = -1; /* use -1 if string is all common */ nodes[i].i = i; nodes[i].d = in->datums[i]; } /* * Sort by label values so that we can group the values into nodes. This * also ensures that the nodes are ordered by label value, allowing the * use of binary search in searchChar. */ qsort(nodes, in->nTuples, sizeof(*nodes), cmpNodePtr); /* And emit results */ out->nNodes = 0; out->nodeLabels = (Datum *) palloc(sizeof(Datum) * in->nTuples); out->mapTuplesToNodes = (int *) palloc(sizeof(int) * in->nTuples); out->leafTupleDatums = (Datum *) palloc(sizeof(Datum) * in->nTuples); for (i = 0; i < in->nTuples; i++) { text *texti = DatumGetTextPP(nodes[i].d); Datum leafD; if (i == 0 || nodes[i].c != nodes[i - 1].c) { out->nodeLabels[out->nNodes] = Int16GetDatum(nodes[i].c); out->nNodes++; } if (commonLen < VARSIZE_ANY_EXHDR(texti)) leafD = formTextDatum(VARDATA_ANY(texti) + commonLen + 1, VARSIZE_ANY_EXHDR(texti) - commonLen - 1); else leafD = formTextDatum(NULL, 0); out->leafTupleDatums[nodes[i].i] = leafD; out->mapTuplesToNodes[nodes[i].i] = out->nNodes - 1; } PG_RETURN_VOID(); } Datum spg_text_inner_consistent(PG_FUNCTION_ARGS) { spgInnerConsistentIn *in = (spgInnerConsistentIn *) PG_GETARG_POINTER(0); spgInnerConsistentOut *out = (spgInnerConsistentOut *) PG_GETARG_POINTER(1); bool collate_is_c = lc_collate_is_c(PG_GET_COLLATION()); text *reconstructedValue; text *reconstrText; int maxReconstrLen; text *prefixText = NULL; int prefixSize = 0; int i; /* * Reconstruct values represented at this tuple, including parent data, * prefix of this tuple if any, and the node label if it's non-dummy. * in->level should be the length of the previously reconstructed value, * and the number of bytes added here is prefixSize or prefixSize + 1. * * Note: we assume that in->reconstructedValue isn't toasted and doesn't * have a short varlena header. This is okay because it must have been * created by a previous invocation of this routine, and we always emit * long-format reconstructed values. */ reconstructedValue = (text *) DatumGetPointer(in->reconstructedValue); Assert(reconstructedValue == NULL ? in->level == 0 : VARSIZE_ANY_EXHDR(reconstructedValue) == in->level); maxReconstrLen = in->level + 1; if (in->hasPrefix) { prefixText = DatumGetTextPP(in->prefixDatum); prefixSize = VARSIZE_ANY_EXHDR(prefixText); maxReconstrLen += prefixSize; } reconstrText = palloc(VARHDRSZ + maxReconstrLen); SET_VARSIZE(reconstrText, VARHDRSZ + maxReconstrLen); if (in->level) memcpy(VARDATA(reconstrText), VARDATA(reconstructedValue), in->level); if (prefixSize) memcpy(((char *) VARDATA(reconstrText)) + in->level, VARDATA_ANY(prefixText), prefixSize); /* last byte of reconstrText will be filled in below */ /* * Scan the child nodes. For each one, complete the reconstructed value * and see if it's consistent with the query. If so, emit an entry into * the output arrays. */ out->nodeNumbers = (int *) palloc(sizeof(int) * in->nNodes); out->levelAdds = (int *) palloc(sizeof(int) * in->nNodes); out->reconstructedValues = (Datum *) palloc(sizeof(Datum) * in->nNodes); out->nNodes = 0; for (i = 0; i < in->nNodes; i++) { int16 nodeChar = DatumGetInt16(in->nodeLabels[i]); int thisLen; bool res = true; int j; /* If nodeChar is a dummy value, don't include it in data */ if (nodeChar <= 0) thisLen = maxReconstrLen - 1; else { ((unsigned char *) VARDATA(reconstrText))[maxReconstrLen - 1] = nodeChar; thisLen = maxReconstrLen; } for (j = 0; j < in->nkeys; j++) { StrategyNumber strategy = in->scankeys[j].sk_strategy; text *inText; int inSize; int r; /* * If it's a collation-aware operator, but the collation is C, we * can treat it as non-collation-aware. With non-C collation we * need to traverse whole tree :-( so there's no point in making * any check here. (Note also that our reconstructed value may * well end with a partial multibyte character, so that applying * any encoding-sensitive test to it would be risky anyhow.) */ if (SPG_IS_COLLATION_AWARE_STRATEGY(strategy)) { if (collate_is_c) strategy -= SPG_STRATEGY_ADDITION; else continue; } inText = DatumGetTextPP(in->scankeys[j].sk_argument); inSize = VARSIZE_ANY_EXHDR(inText); r = memcmp(VARDATA(reconstrText), VARDATA_ANY(inText), Min(inSize, thisLen)); switch (strategy) { case BTLessStrategyNumber: case BTLessEqualStrategyNumber: if (r > 0) res = false; break; case BTEqualStrategyNumber: if (r != 0 || inSize < thisLen) res = false; break; case BTGreaterEqualStrategyNumber: case BTGreaterStrategyNumber: if (r < 0) res = false; break; case RTPrefixStrategyNumber: if (r != 0) res = false; break; default: elog(ERROR, "unrecognized strategy number: %d", in->scankeys[j].sk_strategy); break; } if (!res) break; /* no need to consider remaining conditions */ } if (res) { out->nodeNumbers[out->nNodes] = i; out->levelAdds[out->nNodes] = thisLen - in->level; SET_VARSIZE(reconstrText, VARHDRSZ + thisLen); out->reconstructedValues[out->nNodes] = datumCopy(PointerGetDatum(reconstrText), false, -1); out->nNodes++; } } PG_RETURN_VOID(); } Datum spg_text_leaf_consistent(PG_FUNCTION_ARGS) { spgLeafConsistentIn *in = (spgLeafConsistentIn *) PG_GETARG_POINTER(0); spgLeafConsistentOut *out = (spgLeafConsistentOut *) PG_GETARG_POINTER(1); int level = in->level; text *leafValue, *reconstrValue = NULL; char *fullValue; int fullLen; bool res; int j; /* all tests are exact */ out->recheck = false; leafValue = DatumGetTextPP(in->leafDatum); /* As above, in->reconstructedValue isn't toasted or short. */ if (DatumGetPointer(in->reconstructedValue)) reconstrValue = (text *) DatumGetPointer(in->reconstructedValue); Assert(reconstrValue == NULL ? level == 0 : VARSIZE_ANY_EXHDR(reconstrValue) == level); /* Reconstruct the full string represented by this leaf tuple */ fullLen = level + VARSIZE_ANY_EXHDR(leafValue); if (VARSIZE_ANY_EXHDR(leafValue) == 0 && level > 0) { fullValue = VARDATA(reconstrValue); out->leafValue = PointerGetDatum(reconstrValue); } else { text *fullText = palloc(VARHDRSZ + fullLen); SET_VARSIZE(fullText, VARHDRSZ + fullLen); fullValue = VARDATA(fullText); if (level) memcpy(fullValue, VARDATA(reconstrValue), level); if (VARSIZE_ANY_EXHDR(leafValue) > 0) memcpy(fullValue + level, VARDATA_ANY(leafValue), VARSIZE_ANY_EXHDR(leafValue)); out->leafValue = PointerGetDatum(fullText); } /* Perform the required comparison(s) */ res = true; for (j = 0; j < in->nkeys; j++) { StrategyNumber strategy = in->scankeys[j].sk_strategy; text *query = DatumGetTextPP(in->scankeys[j].sk_argument); int queryLen = VARSIZE_ANY_EXHDR(query); int r; if (strategy == RTPrefixStrategyNumber) { /* * if level >= length of query then reconstrValue must begin with * query (prefix) string, so we don't need to check it again. */ res = (level >= queryLen) || DatumGetBool(DirectFunctionCall2Coll(text_starts_with, PG_GET_COLLATION(), out->leafValue, PointerGetDatum(query))); if (!res) /* no need to consider remaining conditions */ break; continue; } if (SPG_IS_COLLATION_AWARE_STRATEGY(strategy)) { /* Collation-aware comparison */ strategy -= SPG_STRATEGY_ADDITION; /* If asserts enabled, verify encoding of reconstructed string */ Assert(pg_verifymbstr(fullValue, fullLen, false)); r = varstr_cmp(fullValue, fullLen, VARDATA_ANY(query), queryLen, PG_GET_COLLATION()); } else { /* Non-collation-aware comparison */ r = memcmp(fullValue, VARDATA_ANY(query), Min(queryLen, fullLen)); if (r == 0) { if (queryLen > fullLen) r = -1; else if (queryLen < fullLen) r = 1; } } switch (strategy) { case BTLessStrategyNumber: res = (r < 0); break; case BTLessEqualStrategyNumber: res = (r <= 0); break; case BTEqualStrategyNumber: res = (r == 0); break; case BTGreaterEqualStrategyNumber: res = (r >= 0); break; case BTGreaterStrategyNumber: res = (r > 0); break; default: elog(ERROR, "unrecognized strategy number: %d", in->scankeys[j].sk_strategy); res = false; break; } if (!res) break; /* no need to consider remaining conditions */ } PG_RETURN_BOOL(res); }