/*------------------------------------------------------------------------- * * tupdesc.c * POSTGRES tuple descriptor support code * * Portions Copyright (c) 1996-2002, PostgreSQL Global Development Group * Portions Copyright (c) 1994, Regents of the University of California * * * IDENTIFICATION * $Header: /cvsroot/pgsql/src/backend/access/common/tupdesc.c,v 1.82 2002/07/31 17:19:51 tgl Exp $ * * NOTES * some of the executor utility code such as "ExecTypeFromTL" should be * moved here. * *------------------------------------------------------------------------- */ #include "postgres.h" #include "funcapi.h" #include "access/heapam.h" #include "catalog/namespace.h" #include "catalog/pg_type.h" #include "nodes/parsenodes.h" #include "parser/parse_type.h" #include "utils/builtins.h" #include "utils/syscache.h" /* ---------------------------------------------------------------- * CreateTemplateTupleDesc * * This function allocates and zeros a tuple descriptor structure. * ---------------------------------------------------------------- */ TupleDesc CreateTemplateTupleDesc(int natts, hasoid_t withoid) { uint32 size; TupleDesc desc; /* * sanity checks */ AssertArg(natts >= 1); /* * allocate enough memory for the tuple descriptor and zero it as * TupleDescInitEntry assumes that the descriptor is filled with NULL * pointers. */ size = natts * sizeof(Form_pg_attribute); desc = (TupleDesc) palloc(sizeof(struct tupleDesc)); desc->attrs = (Form_pg_attribute *) palloc(size); desc->constr = NULL; MemSet(desc->attrs, 0, size); desc->natts = natts; desc->tdhasoid = withoid; return desc; } /* ---------------------------------------------------------------- * CreateTupleDesc * * This function allocates a new TupleDesc from Form_pg_attribute array * ---------------------------------------------------------------- */ TupleDesc CreateTupleDesc(int natts, Form_pg_attribute *attrs) { TupleDesc desc; /* * sanity checks */ AssertArg(natts >= 1); desc = (TupleDesc) palloc(sizeof(struct tupleDesc)); desc->attrs = attrs; desc->natts = natts; desc->constr = NULL; desc->tdhasoid = UNDEFOID; return desc; } /* ---------------------------------------------------------------- * CreateTupleDescCopy * * This function creates a new TupleDesc by copying from an existing * TupleDesc * * !!! Constraints are not copied !!! * ---------------------------------------------------------------- */ TupleDesc CreateTupleDescCopy(TupleDesc tupdesc) { TupleDesc desc; int i, size; desc = (TupleDesc) palloc(sizeof(struct tupleDesc)); desc->natts = tupdesc->natts; size = desc->natts * sizeof(Form_pg_attribute); desc->attrs = (Form_pg_attribute *) palloc(size); for (i = 0; i < desc->natts; i++) { desc->attrs[i] = (Form_pg_attribute) palloc(ATTRIBUTE_TUPLE_SIZE); memmove(desc->attrs[i], tupdesc->attrs[i], ATTRIBUTE_TUPLE_SIZE); desc->attrs[i]->attnotnull = false; desc->attrs[i]->atthasdef = false; } desc->constr = NULL; desc->tdhasoid = tupdesc->tdhasoid; return desc; } /* ---------------------------------------------------------------- * CreateTupleDescCopyConstr * * This function creates a new TupleDesc by copying from an existing * TupleDesc (with Constraints) * * ---------------------------------------------------------------- */ TupleDesc CreateTupleDescCopyConstr(TupleDesc tupdesc) { TupleDesc desc; TupleConstr *constr = tupdesc->constr; int i, size; desc = (TupleDesc) palloc(sizeof(struct tupleDesc)); desc->natts = tupdesc->natts; size = desc->natts * sizeof(Form_pg_attribute); desc->attrs = (Form_pg_attribute *) palloc(size); for (i = 0; i < desc->natts; i++) { desc->attrs[i] = (Form_pg_attribute) palloc(ATTRIBUTE_TUPLE_SIZE); memmove(desc->attrs[i], tupdesc->attrs[i], ATTRIBUTE_TUPLE_SIZE); } if (constr) { TupleConstr *cpy = (TupleConstr *) palloc(sizeof(TupleConstr)); cpy->has_not_null = constr->has_not_null; if ((cpy->num_defval = constr->num_defval) > 0) { cpy->defval = (AttrDefault *) palloc(cpy->num_defval * sizeof(AttrDefault)); memcpy(cpy->defval, constr->defval, cpy->num_defval * sizeof(AttrDefault)); for (i = cpy->num_defval - 1; i >= 0; i--) { if (constr->defval[i].adbin) cpy->defval[i].adbin = pstrdup(constr->defval[i].adbin); } } if ((cpy->num_check = constr->num_check) > 0) { cpy->check = (ConstrCheck *) palloc(cpy->num_check * sizeof(ConstrCheck)); memcpy(cpy->check, constr->check, cpy->num_check * sizeof(ConstrCheck)); for (i = cpy->num_check - 1; i >= 0; i--) { if (constr->check[i].ccname) cpy->check[i].ccname = pstrdup(constr->check[i].ccname); if (constr->check[i].ccbin) cpy->check[i].ccbin = pstrdup(constr->check[i].ccbin); } } desc->constr = cpy; } else desc->constr = NULL; desc->tdhasoid = tupdesc->tdhasoid; return desc; } void FreeTupleDesc(TupleDesc tupdesc) { int i; for (i = 0; i < tupdesc->natts; i++) pfree(tupdesc->attrs[i]); pfree(tupdesc->attrs); if (tupdesc->constr) { if (tupdesc->constr->num_defval > 0) { AttrDefault *attrdef = tupdesc->constr->defval; for (i = tupdesc->constr->num_defval - 1; i >= 0; i--) { if (attrdef[i].adbin) pfree(attrdef[i].adbin); } pfree(attrdef); } if (tupdesc->constr->num_check > 0) { ConstrCheck *check = tupdesc->constr->check; for (i = tupdesc->constr->num_check - 1; i >= 0; i--) { if (check[i].ccname) pfree(check[i].ccname); if (check[i].ccbin) pfree(check[i].ccbin); } pfree(check); } pfree(tupdesc->constr); } pfree(tupdesc); } bool equalTupleDescs(TupleDesc tupdesc1, TupleDesc tupdesc2) { int i, j, n; if (tupdesc1->natts != tupdesc2->natts) return false; if (tupdesc1->tdhasoid != tupdesc2->tdhasoid) return false; for (i = 0; i < tupdesc1->natts; i++) { Form_pg_attribute attr1 = tupdesc1->attrs[i]; Form_pg_attribute attr2 = tupdesc2->attrs[i]; /* * We do not need to check every single field here: we can * disregard attrelid, attnum (it was used to place the row in the * attrs array) and everything derived from the column datatype. */ if (strcmp(NameStr(attr1->attname), NameStr(attr2->attname)) != 0) return false; if (attr1->atttypid != attr2->atttypid) return false; if (attr1->attstattarget != attr2->attstattarget) return false; if (attr1->atttypmod != attr2->atttypmod) return false; if (attr1->attstorage != attr2->attstorage) return false; if (attr1->attnotnull != attr2->attnotnull) return false; } if (tupdesc1->constr != NULL) { TupleConstr *constr1 = tupdesc1->constr; TupleConstr *constr2 = tupdesc2->constr; if (constr2 == NULL) return false; if (constr1->has_not_null != constr2->has_not_null) return false; n = constr1->num_defval; if (n != (int) constr2->num_defval) return false; for (i = 0; i < n; i++) { AttrDefault *defval1 = constr1->defval + i; AttrDefault *defval2 = constr2->defval; /* * We can't assume that the items are always read from the * system catalogs in the same order; so use the adnum field * to identify the matching item to compare. */ for (j = 0; j < n; defval2++, j++) { if (defval1->adnum == defval2->adnum) break; } if (j >= n) return false; if (strcmp(defval1->adbin, defval2->adbin) != 0) return false; } n = constr1->num_check; if (n != (int) constr2->num_check) return false; for (i = 0; i < n; i++) { ConstrCheck *check1 = constr1->check + i; ConstrCheck *check2 = constr2->check; /* * Similarly, don't assume that the checks are always read in * the same order; match them up by name and contents. (The * name *should* be unique, but...) */ for (j = 0; j < n; check2++, j++) { if (strcmp(check1->ccname, check2->ccname) == 0 && strcmp(check1->ccbin, check2->ccbin) == 0) break; } if (j >= n) return false; } } else if (tupdesc2->constr != NULL) return false; return true; } /* ---------------------------------------------------------------- * TupleDescInitEntry * * This function initializes a single attribute structure in * a preallocated tuple descriptor. * ---------------------------------------------------------------- */ void TupleDescInitEntry(TupleDesc desc, AttrNumber attributeNumber, char *attributeName, Oid oidtypeid, int32 typmod, int attdim, bool attisset) { HeapTuple tuple; Form_pg_type typeForm; Form_pg_attribute att; /* * sanity checks */ AssertArg(PointerIsValid(desc)); AssertArg(attributeNumber >= 1); /* * attributeName's are sometimes NULL, from resdom's. I don't know * why that is, though -- Jolly */ /* AssertArg(NameIsValid(attributeName));*/ AssertArg(!PointerIsValid(desc->attrs[attributeNumber - 1])); /* * allocate storage for this attribute */ att = (Form_pg_attribute) palloc(ATTRIBUTE_TUPLE_SIZE); desc->attrs[attributeNumber - 1] = att; /* * initialize the attribute fields */ att->attrelid = 0; /* dummy value */ if (attributeName != NULL) namestrcpy(&(att->attname), attributeName); else MemSet(NameStr(att->attname), 0, NAMEDATALEN); att->attstattarget = -1; att->attcacheoff = -1; att->atttypmod = typmod; att->attnum = attributeNumber; att->attndims = attdim; att->attisset = attisset; att->attnotnull = false; att->atthasdef = false; tuple = SearchSysCache(TYPEOID, ObjectIdGetDatum(oidtypeid), 0, 0, 0); if (!HeapTupleIsValid(tuple)) elog(ERROR, "Unable to look up type id %u", oidtypeid); /* * type info exists so we initialize our attribute information from * the type tuple we found.. */ typeForm = (Form_pg_type) GETSTRUCT(tuple); att->atttypid = HeapTupleGetOid(tuple); /* * There are a couple of cases where we must override the information * stored in pg_type. * * First: if this attribute is a set, what is really stored in the * attribute is the OID of a tuple in the pg_proc catalog. The pg_proc * tuple contains the query string which defines this set - i.e., the * query to run to get the set. So the atttypid (just assigned above) * refers to the type returned by this query, but the actual length of * this attribute is the length (size) of an OID. * * (Why not just make the atttypid point to the OID type, instead of the * type the query returns? Because the executor uses the atttypid to * tell the front end what type will be returned, * and in the end the type returned will be the result of the query, * not an OID.) * * (Why not wait until the return type of the set is known (i.e., the * recursive call to the executor to execute the set has returned) * before telling the front end what the return type will be? Because * the executor is a delicate thing, and making sure that the correct * order of front-end commands is maintained is messy, especially * considering that target lists may change as inherited attributes * are considered, etc. Ugh.) * * Second: if we are dealing with a complex type (a tuple type), then * pg_type will say that the representation is the same as Oid. But * if typmod is sizeof(Pointer) then the internal representation is * actually a pointer to a TupleTableSlot, and we have to substitute * that information. * * A set of complex type is first and foremost a set, so its * representation is Oid not pointer. So, test that case first. */ if (attisset) { att->attlen = sizeof(Oid); att->attbyval = true; att->attalign = 'i'; att->attstorage = 'p'; } else if (typeForm->typtype == 'c' && typmod == sizeof(Pointer)) { att->attlen = sizeof(Pointer); att->attbyval = true; att->attalign = 'd'; /* kluge to work with 8-byte pointers */ /* XXX ought to have a separate attalign value for pointers ... */ att->attstorage = 'p'; } else { att->attlen = typeForm->typlen; att->attbyval = typeForm->typbyval; att->attalign = typeForm->typalign; att->attstorage = typeForm->typstorage; } ReleaseSysCache(tuple); } /* * BuildDescForRelation * * Given a relation schema (list of ColumnDef nodes), build a TupleDesc. */ TupleDesc BuildDescForRelation(List *schema) { int natts; AttrNumber attnum; List *p; TupleDesc desc; AttrDefault *attrdef = NULL; TupleConstr *constr = (TupleConstr *) palloc(sizeof(TupleConstr)); char *attname; int32 atttypmod; int attdim; int ndef = 0; bool attisset; /* * allocate a new tuple descriptor */ natts = length(schema); desc = CreateTemplateTupleDesc(natts, UNDEFOID); constr->has_not_null = false; attnum = 0; foreach(p, schema) { ColumnDef *entry = lfirst(p); /* * for each entry in the list, get the name and type information * from the list and have TupleDescInitEntry fill in the attribute * information we need. */ attnum++; attname = entry->colname; attisset = entry->typename->setof; atttypmod = entry->typename->typmod; attdim = length(entry->typename->arrayBounds); TupleDescInitEntry(desc, attnum, attname, typenameTypeId(entry->typename), atttypmod, attdim, attisset); /* This is for constraints */ if (entry->is_not_null) constr->has_not_null = true; desc->attrs[attnum - 1]->attnotnull = entry->is_not_null; /* * Note we copy only pre-cooked default expressions. Digestion of * raw ones is someone else's problem. */ if (entry->cooked_default != NULL) { if (attrdef == NULL) attrdef = (AttrDefault *) palloc(natts * sizeof(AttrDefault)); attrdef[ndef].adnum = attnum; attrdef[ndef].adbin = pstrdup(entry->cooked_default); ndef++; desc->attrs[attnum - 1]->atthasdef = true; } } if (constr->has_not_null || ndef > 0) { desc->constr = constr; if (ndef > 0) /* DEFAULTs */ { if (ndef < natts) constr->defval = (AttrDefault *) repalloc(attrdef, ndef * sizeof(AttrDefault)); else constr->defval = attrdef; constr->num_defval = ndef; } else { constr->defval = NULL; constr->num_defval = 0; } constr->check = NULL; constr->num_check = 0; } else { pfree(constr); desc->constr = NULL; } return desc; } /* * RelationNameGetTupleDesc * * Given a (possibly qualified) relation name, build a TupleDesc. */ TupleDesc RelationNameGetTupleDesc(char *relname) { RangeVar *relvar; Relation rel; TupleDesc tupdesc; List *relname_list; /* Open relation and get the tuple description */ relname_list = stringToQualifiedNameList(relname, "RelationNameGetTupleDesc"); relvar = makeRangeVarFromNameList(relname_list); rel = heap_openrv(relvar, AccessShareLock); tupdesc = CreateTupleDescCopy(RelationGetDescr(rel)); relation_close(rel, AccessShareLock); return tupdesc; } /* * TypeGetTupleDesc * * Given a type Oid, build a TupleDesc. * * If the type is composite, *and* a colaliases List is provided, *and* * the List is of natts length, use the aliases instead of the relation * attnames. * * If the type is a base type, a single item alias List is required. */ TupleDesc TypeGetTupleDesc(Oid typeoid, List *colaliases) { Oid relid = typeidTypeRelid(typeoid); TupleDesc tupdesc; /* * Build a suitable tupledesc representing the output rows */ if (OidIsValid(relid)) { /* Composite data type, i.e. a table's row type */ Relation rel; int natts; rel = relation_open(relid, AccessShareLock); tupdesc = CreateTupleDescCopy(RelationGetDescr(rel)); natts = tupdesc->natts; relation_close(rel, AccessShareLock); /* check to see if we've given column aliases */ if(colaliases != NIL) { char *label; int varattno; /* does the List length match the number of attributes */ if (length(colaliases) != natts) elog(ERROR, "TypeGetTupleDesc: number of aliases does not match number of attributes"); /* OK, use the aliases instead */ for (varattno = 0; varattno < natts; varattno++) { label = strVal(nth(varattno, colaliases)); if (label != NULL) namestrcpy(&(tupdesc->attrs[varattno]->attname), label); else MemSet(NameStr(tupdesc->attrs[varattno]->attname), 0, NAMEDATALEN); } } } else { /* Must be a base data type, i.e. scalar */ char *attname; /* the alias List is required for base types */ if (colaliases == NIL) elog(ERROR, "TypeGetTupleDesc: no column alias was provided"); /* the alias List length must be 1 */ if (length(colaliases) != 1) elog(ERROR, "TypeGetTupleDesc: number of aliases does not match number of attributes"); /* OK, get the column alias */ attname = strVal(lfirst(colaliases)); tupdesc = CreateTemplateTupleDesc(1, WITHOUTOID); TupleDescInitEntry(tupdesc, (AttrNumber) 1, attname, typeoid, -1, 0, false); } return tupdesc; }