/* * * outfuncs.c * routines to convert a node to ascii representation * * Portions Copyright (c) 1996-2000, PostgreSQL, Inc * Portions Copyright (c) 1994, Regents of the University of California * * $Header: /cvsroot/pgsql/src/backend/nodes/outfuncs.c,v 1.121 2000/07/12 02:37:06 tgl Exp $ * * NOTES * Every (plan) node in POSTGRES has an associated "out" routine which * knows how to create its ascii representation. These functions are * useful for debugging as well as for storing plans in the system * catalogs (eg. indexes). This is also the plan string sent out in * Mariposa. * * These functions update the in/out argument of type StringInfo * passed to them. This argument contains the string holding the ASCII * representation plus some other information (string length, etc.) * */ #include #include "postgres.h" #include "access/heapam.h" #include "access/htup.h" #include "catalog/pg_type.h" #include "fmgr.h" #include "lib/stringinfo.h" #include "nodes/execnodes.h" #include "nodes/nodes.h" #include "nodes/parsenodes.h" #include "nodes/pg_list.h" #include "nodes/plannodes.h" #include "nodes/primnodes.h" #include "nodes/relation.h" #include "parser/parse.h" #include "utils/datum.h" #include "utils/lsyscache.h" #include "utils/syscache.h" static void _outDatum(StringInfo str, Datum value, Oid type); static void _outNode(StringInfo str, void *obj); /* * _outToken * Convert an ordinary string (eg, an identifier) into a form that * will be decoded back to a plain token by read.c's functions. * * If a null or empty string is given, it is encoded as "<>". */ static void _outToken(StringInfo str, char *s) { if (s == NULL || *s == '\0') { appendStringInfo(str, "<>"); return; } /* * Look for characters or patterns that are treated specially by * read.c (either in lsptok() or in nodeRead()), and therefore need a * protective backslash. */ /* These characters only need to be quoted at the start of the string */ if (*s == '<' || *s == '\"' || *s == '@' || isdigit((int) *s) || (*s == '-' && isdigit((int) s[1]))) appendStringInfoChar(str, '\\'); while (*s) { /* These chars must be backslashed anywhere in the string */ if (*s == ' ' || *s == '\n' || *s == '\t' || *s == '(' || *s == ')' || *s == '{' || *s == '}' || *s == '\\') appendStringInfoChar(str, '\\'); appendStringInfoChar(str, *s++); } } /* * _outIntList - * converts a List of integers */ static void _outIntList(StringInfo str, List *list) { List *l; appendStringInfoChar(str, '('); foreach(l, list) appendStringInfo(str, " %d", lfirsti(l)); appendStringInfoChar(str, ')'); } static void _outCreateStmt(StringInfo str, CreateStmt *node) { appendStringInfo(str, " CREATE :relname "); _outToken(str, node->relname); appendStringInfo(str, " :istemp %s ", node->istemp ? "true" : "false"); appendStringInfo(str, " :columns "); _outNode(str, node->tableElts); appendStringInfo(str, " :inhRelnames "); _outNode(str, node->inhRelnames); appendStringInfo(str, " :constraints "); _outNode(str, node->constraints); } static void _outIndexStmt(StringInfo str, IndexStmt *node) { appendStringInfo(str, " INDEX :idxname "); _outToken(str, node->idxname); appendStringInfo(str, " :relname "); _outToken(str, node->relname); appendStringInfo(str, " :accessMethod "); _outToken(str, node->accessMethod); appendStringInfo(str, " :indexParams "); _outNode(str, node->indexParams); appendStringInfo(str, " :withClause "); _outNode(str, node->withClause); appendStringInfo(str, " :whereClause "); _outNode(str, node->whereClause); appendStringInfo(str, " :rangetable "); _outNode(str, node->rangetable); appendStringInfo(str, " :lossy %s :unique %s ", node->lossy ? "true" : "false", node->unique ? "true" : "false"); } static void _outSelectStmt(StringInfo str, SelectStmt *node) { appendStringInfo(str, "SELECT :where "); _outNode(str, node->whereClause); } static void _outFuncCall(StringInfo str, FuncCall *node) { appendStringInfo(str, "FUNCTION "); _outToken(str, node->funcname); appendStringInfo(str, " :args "); _outNode(str, node->args); appendStringInfo(str, " :agg_star %s :agg_distinct %s ", node->agg_star ? "true" : "false", node->agg_distinct ? "true" : "false"); } static void _outColumnDef(StringInfo str, ColumnDef *node) { appendStringInfo(str, " COLUMNDEF :colname "); _outToken(str, node->colname); appendStringInfo(str, " :typename "); _outNode(str, node->typename); appendStringInfo(str, " :is_not_null %s :is_sequence %s :raw_default ", node->is_not_null ? "true" : "false", node->is_sequence ? "true" : "false"); _outNode(str, node->raw_default); appendStringInfo(str, " :cooked_default "); _outToken(str, node->cooked_default); appendStringInfo(str, " :constraints "); _outNode(str, node->constraints); } static void _outTypeName(StringInfo str, TypeName *node) { appendStringInfo(str, " TYPENAME :name "); _outToken(str, node->name); appendStringInfo(str, " :timezone %s :setof %s typmod %d :arrayBounds ", node->timezone ? "true" : "false", node->setof ? "true" : "false", node->typmod); _outNode(str, node->arrayBounds); } static void _outTypeCast(StringInfo str, TypeCast *node) { appendStringInfo(str, " TYPECAST :arg "); _outNode(str, node->arg); appendStringInfo(str, " :typename "); _outNode(str, node->typename); } static void _outIndexElem(StringInfo str, IndexElem *node) { appendStringInfo(str, " INDEXELEM :name "); _outToken(str, node->name); appendStringInfo(str, " :args "); _outNode(str, node->args); appendStringInfo(str, " :class "); _outToken(str, node->class); appendStringInfo(str, " :typename "); _outNode(str, node->typename); } static void _outQuery(StringInfo str, Query *node) { appendStringInfo(str, " QUERY :command %d ", node->commandType); if (node->utilityStmt) { switch (nodeTag(node->utilityStmt)) { case T_CreateStmt: appendStringInfo(str, " :create "); _outToken(str, ((CreateStmt *) (node->utilityStmt))->relname); appendStringInfo(str, " "); _outNode(str, node->utilityStmt); break; case T_IndexStmt: appendStringInfo(str, " :index "); _outToken(str, ((IndexStmt *) (node->utilityStmt))->idxname); appendStringInfo(str, " on "); _outToken(str, ((IndexStmt *) (node->utilityStmt))->relname); appendStringInfo(str, " "); _outNode(str, node->utilityStmt); break; case T_NotifyStmt: appendStringInfo(str, " :utility "); _outToken(str, ((NotifyStmt *) (node->utilityStmt))->relname); break; default: appendStringInfo(str, " :utility ? "); } } else appendStringInfo(str, " :utility <>"); appendStringInfo(str, " :resultRelation %u :into ", node->resultRelation); _outToken(str, node->into); appendStringInfo(str, " :isPortal %s :isBinary %s :isTemp %s :unionall %s :distinctClause ", node->isPortal ? "true" : "false", node->isBinary ? "true" : "false", node->isTemp ? "true" : "false", node->unionall ? "true" : "false"); _outNode(str, node->distinctClause); appendStringInfo(str, " :sortClause "); _outNode(str, node->sortClause); appendStringInfo(str, " :rtable "); _outNode(str, node->rtable); appendStringInfo(str, " :targetlist "); _outNode(str, node->targetList); appendStringInfo(str, " :qual "); _outNode(str, node->qual); appendStringInfo(str, " :groupClause "); _outNode(str, node->groupClause); appendStringInfo(str, " :havingQual "); _outNode(str, node->havingQual); appendStringInfo(str, " :hasAggs %s :hasSubLinks %s :unionClause ", node->hasAggs ? "true" : "false", node->hasSubLinks ? "true" : "false"); _outNode(str, node->unionClause); appendStringInfo(str, " :intersectClause "); _outNode(str, node->intersectClause); appendStringInfo(str, " :limitOffset "); _outNode(str, node->limitOffset); appendStringInfo(str, " :limitCount "); _outNode(str, node->limitCount); appendStringInfo(str, " :rowMark "); _outNode(str, node->rowMark); } static void _outSortClause(StringInfo str, SortClause *node) { appendStringInfo(str, " SORTCLAUSE :tleSortGroupRef %d :sortop %u ", node->tleSortGroupRef, node->sortop); } static void _outGroupClause(StringInfo str, GroupClause *node) { appendStringInfo(str, " GROUPCLAUSE :tleSortGroupRef %d :sortop %u ", node->tleSortGroupRef, node->sortop); } /* * print the basic stuff of all nodes that inherit from Plan */ static void _outPlanInfo(StringInfo str, Plan *node) { appendStringInfo(str, ":startup_cost %.2f :total_cost %.2f :rows %.0f :width %d :state %s :qptargetlist ", node->startup_cost, node->total_cost, node->plan_rows, node->plan_width, node->state ? "not-NULL" : "<>"); _outNode(str, node->targetlist); appendStringInfo(str, " :qpqual "); _outNode(str, node->qual); appendStringInfo(str, " :lefttree "); _outNode(str, node->lefttree); appendStringInfo(str, " :righttree "); _outNode(str, node->righttree); appendStringInfo(str, " :extprm "); _outIntList(str, node->extParam); appendStringInfo(str, " :locprm "); _outIntList(str, node->locParam); appendStringInfo(str, " :initplan "); _outNode(str, node->initPlan); appendStringInfo(str, " :nprm %d ", node->nParamExec); } /* * Stuff from plannodes.h */ static void _outPlan(StringInfo str, Plan *node) { appendStringInfo(str, " PLAN "); _outPlanInfo(str, (Plan *) node); } static void _outResult(StringInfo str, Result *node) { appendStringInfo(str, " RESULT "); _outPlanInfo(str, (Plan *) node); appendStringInfo(str, " :resconstantqual "); _outNode(str, node->resconstantqual); } /* * Append is a subclass of Plan. */ static void _outAppend(StringInfo str, Append *node) { appendStringInfo(str, " APPEND "); _outPlanInfo(str, (Plan *) node); appendStringInfo(str, " :appendplans "); _outNode(str, node->appendplans); appendStringInfo(str, " :unionrtables "); _outNode(str, node->unionrtables); appendStringInfo(str, " :inheritrelid %u :inheritrtable ", node->inheritrelid); _outNode(str, node->inheritrtable); } /* * Join is a subclass of Plan */ static void _outJoin(StringInfo str, Join *node) { appendStringInfo(str, " JOIN "); _outPlanInfo(str, (Plan *) node); } /* * NestLoop is a subclass of Join */ static void _outNestLoop(StringInfo str, NestLoop *node) { appendStringInfo(str, " NESTLOOP "); _outPlanInfo(str, (Plan *) node); } /* * MergeJoin is a subclass of Join */ static void _outMergeJoin(StringInfo str, MergeJoin *node) { appendStringInfo(str, " MERGEJOIN "); _outPlanInfo(str, (Plan *) node); appendStringInfo(str, " :mergeclauses "); _outNode(str, node->mergeclauses); } /* * HashJoin is a subclass of Join. */ static void _outHashJoin(StringInfo str, HashJoin *node) { appendStringInfo(str, " HASHJOIN "); _outPlanInfo(str, (Plan *) node); appendStringInfo(str, " :hashclauses "); _outNode(str, node->hashclauses); appendStringInfo(str, " :hashjoinop %u ", node->hashjoinop); appendStringInfo(str, " :hashdone %d ", node->hashdone); } static void _outSubPlan(StringInfo str, SubPlan *node) { appendStringInfo(str, " SUBPLAN :plan "); _outNode(str, node->plan); appendStringInfo(str, " :planid %u :rtable ", node->plan_id); _outNode(str, node->rtable); appendStringInfo(str, " :setprm "); _outIntList(str, node->setParam); appendStringInfo(str, " :parprm "); _outIntList(str, node->parParam); appendStringInfo(str, " :slink "); _outNode(str, node->sublink); } /* * Scan is a subclass of Node */ static void _outScan(StringInfo str, Scan *node) { appendStringInfo(str, " SCAN "); _outPlanInfo(str, (Plan *) node); appendStringInfo(str, " :scanrelid %u ", node->scanrelid); } /* * SeqScan is a subclass of Scan */ static void _outSeqScan(StringInfo str, SeqScan *node) { appendStringInfo(str, " SEQSCAN "); _outPlanInfo(str, (Plan *) node); appendStringInfo(str, " :scanrelid %u ", node->scanrelid); } /* * IndexScan is a subclass of Scan */ static void _outIndexScan(StringInfo str, IndexScan *node) { appendStringInfo(str, " INDEXSCAN "); _outPlanInfo(str, (Plan *) node); appendStringInfo(str, " :scanrelid %u :indxid ", node->scan.scanrelid); _outIntList(str, node->indxid); appendStringInfo(str, " :indxqual "); _outNode(str, node->indxqual); appendStringInfo(str, " :indxqualorig "); _outNode(str, node->indxqualorig); appendStringInfo(str, " :indxorderdir %d ", node->indxorderdir); } /* * TidScan is a subclass of Scan */ static void _outTidScan(StringInfo str, TidScan *node) { appendStringInfo(str, " TIDSCAN "); _outPlanInfo(str, (Plan *) node); appendStringInfo(str, " :scanrelid %u ", node->scan.scanrelid); appendStringInfo(str, " :needrescan %d ", node->needRescan); appendStringInfo(str, " :tideval "); _outNode(str, node->tideval); } /* * Material is a subclass of Plan */ static void _outMaterial(StringInfo str, Material *node) { appendStringInfo(str, " MATERIAL "); _outPlanInfo(str, (Plan *) node); } /* * Sort is a subclass of Plan */ static void _outSort(StringInfo str, Sort *node) { appendStringInfo(str, " SORT "); _outPlanInfo(str, (Plan *) node); appendStringInfo(str, " :keycount %d ", node->keycount); } static void _outAgg(StringInfo str, Agg *node) { appendStringInfo(str, " AGG "); _outPlanInfo(str, (Plan *) node); } static void _outGroup(StringInfo str, Group *node) { appendStringInfo(str, " GRP "); _outPlanInfo(str, (Plan *) node); /* the actual Group fields */ appendStringInfo(str, " :numCols %d :tuplePerGroup %s ", node->numCols, node->tuplePerGroup ? "true" : "false"); } static void _outUnique(StringInfo str, Unique *node) { int i; appendStringInfo(str, " UNIQUE "); _outPlanInfo(str, (Plan *) node); appendStringInfo(str, " :numCols %d :uniqColIdx ", node->numCols); for (i = 0; i < node->numCols; i++) appendStringInfo(str, "%d ", (int) node->uniqColIdx[i]); } /* * Hash is a subclass of Plan */ static void _outHash(StringInfo str, Hash *node) { appendStringInfo(str, " HASH "); _outPlanInfo(str, (Plan *) node); appendStringInfo(str, " :hashkey "); _outNode(str, node->hashkey); } /***************************************************************************** * * Stuff from primnodes.h. * *****************************************************************************/ /* * Resdom is a subclass of Node */ static void _outResdom(StringInfo str, Resdom *node) { appendStringInfo(str, " RESDOM :resno %d :restype %u :restypmod %d :resname ", node->resno, node->restype, node->restypmod); _outToken(str, node->resname); appendStringInfo(str, " :reskey %d :reskeyop %u :ressortgroupref %d :resjunk %s ", node->reskey, node->reskeyop, node->ressortgroupref, node->resjunk ? "true" : "false"); } static void _outFjoin(StringInfo str, Fjoin *node) { int i; appendStringInfo(str, " FJOIN :initialized %s :nNodes %d ", node->fj_initialized ? "true" : "false", node->fj_nNodes); appendStringInfo(str, " :innerNode "); _outNode(str, node->fj_innerNode); appendStringInfo(str, " :results @ 0x%x :alwaysdone", (int) node->fj_results); for (i = 0; i < node->fj_nNodes; i++) appendStringInfo(str, (node->fj_alwaysDone[i]) ? "true" : "false"); } /* * Expr is a subclass of Node */ static void _outExpr(StringInfo str, Expr *node) { char *opstr = NULL; appendStringInfo(str, " EXPR :typeOid %u ", node->typeOid); switch (node->opType) { case OP_EXPR: opstr = "op"; break; case FUNC_EXPR: opstr = "func"; break; case OR_EXPR: opstr = "or"; break; case AND_EXPR: opstr = "and"; break; case NOT_EXPR: opstr = "not"; break; case SUBPLAN_EXPR: opstr = "subp"; break; } appendStringInfo(str, " :opType "); _outToken(str, opstr); appendStringInfo(str, " :oper "); _outNode(str, node->oper); appendStringInfo(str, " :args "); _outNode(str, node->args); } /* * Var is a subclass of Expr */ static void _outVar(StringInfo str, Var *node) { appendStringInfo(str, " VAR :varno %d :varattno %d :vartype %u :vartypmod %d ", node->varno, node->varattno, node->vartype, node->vartypmod); appendStringInfo(str, " :varlevelsup %u :varnoold %d :varoattno %d", node->varlevelsup, node->varnoold, node->varoattno); } /* * Const is a subclass of Expr */ static void _outConst(StringInfo str, Const *node) { appendStringInfo(str, " CONST :consttype %u :constlen %d :constisnull %s :constvalue ", node->consttype, node->constlen, node->constisnull ? "true" : "false"); if (node->constisnull) appendStringInfo(str, "<>"); else _outDatum(str, node->constvalue, node->consttype); appendStringInfo(str, " :constbyval %s ", node->constbyval ? "true" : "false"); } /* * Aggref */ static void _outAggref(StringInfo str, Aggref *node) { appendStringInfo(str, " AGGREG :aggname "); _outToken(str, node->aggname); appendStringInfo(str, " :basetype %u :aggtype %u :target ", node->basetype, node->aggtype); _outNode(str, node->target); appendStringInfo(str, " :usenulls %s :aggstar %s :aggdistinct %s ", node->usenulls ? "true" : "false", node->aggstar ? "true" : "false", node->aggdistinct ? "true" : "false"); /* aggno is not dumped */ } /* * SubLink */ static void _outSubLink(StringInfo str, SubLink *node) { appendStringInfo(str, " SUBLINK :subLinkType %d :useor %s :lefthand ", node->subLinkType, node->useor ? "true" : "false"); _outNode(str, node->lefthand); appendStringInfo(str, " :oper "); _outNode(str, node->oper); appendStringInfo(str, " :subselect "); _outNode(str, node->subselect); } /* * RelabelType */ static void _outRelabelType(StringInfo str, RelabelType *node) { appendStringInfo(str, " RELABELTYPE :arg "); _outNode(str, node->arg); appendStringInfo(str, " :resulttype %u :resulttypmod %d ", node->resulttype, node->resulttypmod); } /* * Array is a subclass of Expr */ static void _outArray(StringInfo str, Array *node) { int i; appendStringInfo(str, " ARRAY :arrayelemtype %u :arrayelemlength %d :arrayelembyval %c ", node->arrayelemtype, node->arrayelemlength, node->arrayelembyval ? 't' : 'f'); appendStringInfo(str, " :arrayndim %d :arraylow ", node->arrayndim); for (i = 0; i < node->arrayndim; i++) appendStringInfo(str, " %d ", node->arraylow.indx[i]); appendStringInfo(str, " :arrayhigh "); for (i = 0; i < node->arrayndim; i++) appendStringInfo(str, " %d ", node->arrayhigh.indx[i]); appendStringInfo(str, " :arraylen %d ", node->arraylen); } /* * ArrayRef is a subclass of Expr */ static void _outArrayRef(StringInfo str, ArrayRef *node) { appendStringInfo(str, " ARRAYREF :refelemtype %u :refattrlength %d :refelemlength %d ", node->refelemtype, node->refattrlength, node->refelemlength); appendStringInfo(str, " :refelembyval %c :refupperindex ", node->refelembyval ? 't' : 'f'); _outNode(str, node->refupperindexpr); appendStringInfo(str, " :reflowerindex "); _outNode(str, node->reflowerindexpr); appendStringInfo(str, " :refexpr "); _outNode(str, node->refexpr); appendStringInfo(str, " :refassgnexpr "); _outNode(str, node->refassgnexpr); } /* * Func is a subclass of Expr */ static void _outFunc(StringInfo str, Func *node) { appendStringInfo(str, " FUNC :funcid %u :functype %u :funcisindex %s :funcsize %d ", node->funcid, node->functype, node->funcisindex ? "true" : "false", node->funcsize); appendStringInfo(str, " :func_fcache @ 0x%x :func_tlist ", (int) node->func_fcache); _outNode(str, node->func_tlist); appendStringInfo(str, " :func_planlist "); _outNode(str, node->func_planlist); } /* * Oper is a subclass of Expr */ static void _outOper(StringInfo str, Oper *node) { appendStringInfo(str, " OPER :opno %u :opid %u :opresulttype %u ", node->opno, node->opid, node->opresulttype); } /* * Param is a subclass of Expr */ static void _outParam(StringInfo str, Param *node) { appendStringInfo(str, " PARAM :paramkind %d :paramid %d :paramname ", node->paramkind, node->paramid); _outToken(str, node->paramname); appendStringInfo(str, " :paramtype %u :param_tlist ", node->paramtype); _outNode(str, node->param_tlist); } /* * Stuff from execnodes.h */ /* * EState is a subclass of Node. */ static void _outEState(StringInfo str, EState *node) { appendStringInfo(str, " ESTATE :direction %d :range_table ", node->es_direction); _outNode(str, node->es_range_table); appendStringInfo(str, " :result_relation_info @ 0x%x ", (int) (node->es_result_relation_info)); } /* * Stuff from relation.h */ static void _outRelOptInfo(StringInfo str, RelOptInfo *node) { appendStringInfo(str, " RELOPTINFO :relids "); _outIntList(str, node->relids); appendStringInfo(str, " :rows %.0f :width %d :indexed %s :pages %ld :tuples %.0f :targetlist ", node->rows, node->width, node->indexed ? "true" : "false", node->pages, node->tuples); _outNode(str, node->targetlist); appendStringInfo(str, " :pathlist "); _outNode(str, node->pathlist); appendStringInfo(str, " :cheapest_startup_path "); _outNode(str, node->cheapest_startup_path); appendStringInfo(str, " :cheapest_total_path "); _outNode(str, node->cheapest_total_path); appendStringInfo(str, " :pruneable %s :baserestrictinfo ", node->pruneable ? "true" : "false"); _outNode(str, node->baserestrictinfo); appendStringInfo(str, " :joininfo "); _outNode(str, node->joininfo); appendStringInfo(str, " :innerjoin "); _outNode(str, node->innerjoin); } static void _outIndexOptInfo(StringInfo str, IndexOptInfo *node) { appendStringInfo(str, " INDEXOPTINFO :indexoid %u :pages %ld :tuples %g ", node->indexoid, node->pages, node->tuples); } /* * TargetEntry is a subclass of Node. */ static void _outTargetEntry(StringInfo str, TargetEntry *node) { appendStringInfo(str, " TARGETENTRY :resdom "); _outNode(str, node->resdom); appendStringInfo(str, " :expr "); _outNode(str, node->expr); } static void _outRangeTblEntry(StringInfo str, RangeTblEntry *node) { appendStringInfo(str, " RTE :relname "); _outToken(str, node->relname); appendStringInfo(str, " :ref "); _outNode(str, node->ref); appendStringInfo(str, " :relid %u :inh %s :inFromCl %s :inJoinSet %s :skipAcl %s", node->relid, node->inh ? "true" : "false", node->inFromCl ? "true" : "false", node->inJoinSet ? "true" : "false", node->skipAcl ? "true" : "false"); } static void _outRowMark(StringInfo str, RowMark *node) { appendStringInfo(str, " ROWMARK :rti %u :info %u", node->rti, node->info); } /* * Path is a subclass of Node. */ static void _outPath(StringInfo str, Path *node) { appendStringInfo(str, " PATH :pathtype %d :startup_cost %.2f :total_cost %.2f :pathkeys ", node->pathtype, node->startup_cost, node->total_cost); _outNode(str, node->pathkeys); } /* * IndexPath is a subclass of Path. */ static void _outIndexPath(StringInfo str, IndexPath *node) { appendStringInfo(str, " INDEXPATH :pathtype %d :startup_cost %.2f :total_cost %.2f :pathkeys ", node->path.pathtype, node->path.startup_cost, node->path.total_cost); _outNode(str, node->path.pathkeys); appendStringInfo(str, " :indexid "); _outIntList(str, node->indexid); appendStringInfo(str, " :indexqual "); _outNode(str, node->indexqual); appendStringInfo(str, " :indexscandir %d :joinrelids ", (int) node->indexscandir); _outIntList(str, node->joinrelids); appendStringInfo(str, " :rows %.2f ", node->rows); } /* * TidPath is a subclass of Path. */ static void _outTidPath(StringInfo str, TidPath *node) { appendStringInfo(str, " TIDPATH :pathtype %d :startup_cost %.2f :total_cost %.2f :pathkeys ", node->path.pathtype, node->path.startup_cost, node->path.total_cost); _outNode(str, node->path.pathkeys); appendStringInfo(str, " :tideval "); _outNode(str, node->tideval); appendStringInfo(str, " :un joined_relids "); _outIntList(str, node->unjoined_relids); } /* * NestPath is a subclass of Path */ static void _outNestPath(StringInfo str, NestPath *node) { appendStringInfo(str, " NESTPATH :pathtype %d :startup_cost %.2f :total_cost %.2f :pathkeys ", node->path.pathtype, node->path.startup_cost, node->path.total_cost); _outNode(str, node->path.pathkeys); appendStringInfo(str, " :outerjoinpath "); _outNode(str, node->outerjoinpath); appendStringInfo(str, " :innerjoinpath "); _outNode(str, node->innerjoinpath); appendStringInfo(str, " :joinrestrictinfo "); _outNode(str, node->joinrestrictinfo); } /* * MergePath is a subclass of NestPath. */ static void _outMergePath(StringInfo str, MergePath *node) { appendStringInfo(str, " MERGEPATH :pathtype %d :startup_cost %.2f :total_cost %.2f :pathkeys ", node->jpath.path.pathtype, node->jpath.path.startup_cost, node->jpath.path.total_cost); _outNode(str, node->jpath.path.pathkeys); appendStringInfo(str, " :outerjoinpath "); _outNode(str, node->jpath.outerjoinpath); appendStringInfo(str, " :innerjoinpath "); _outNode(str, node->jpath.innerjoinpath); appendStringInfo(str, " :joinrestrictinfo "); _outNode(str, node->jpath.joinrestrictinfo); appendStringInfo(str, " :path_mergeclauses "); _outNode(str, node->path_mergeclauses); appendStringInfo(str, " :outersortkeys "); _outNode(str, node->outersortkeys); appendStringInfo(str, " :innersortkeys "); _outNode(str, node->innersortkeys); } /* * HashPath is a subclass of NestPath. */ static void _outHashPath(StringInfo str, HashPath *node) { appendStringInfo(str, " HASHPATH :pathtype %d :startup_cost %.2f :total_cost %.2f :pathkeys ", node->jpath.path.pathtype, node->jpath.path.startup_cost, node->jpath.path.total_cost); _outNode(str, node->jpath.path.pathkeys); appendStringInfo(str, " :outerjoinpath "); _outNode(str, node->jpath.outerjoinpath); appendStringInfo(str, " :innerjoinpath "); _outNode(str, node->jpath.innerjoinpath); appendStringInfo(str, " :joinrestrictinfo "); _outNode(str, node->jpath.joinrestrictinfo); appendStringInfo(str, " :path_hashclauses "); _outNode(str, node->path_hashclauses); } /* * PathKeyItem is a subclass of Node. */ static void _outPathKeyItem(StringInfo str, PathKeyItem *node) { appendStringInfo(str, " PATHKEYITEM :sortop %u :key ", node->sortop); _outNode(str, node->key); } /* * RestrictInfo is a subclass of Node. */ static void _outRestrictInfo(StringInfo str, RestrictInfo *node) { appendStringInfo(str, " RESTRICTINFO :clause "); _outNode(str, node->clause); appendStringInfo(str, " :subclauseindices "); _outNode(str, node->subclauseindices); appendStringInfo(str, " :mergejoinoperator %u ", node->mergejoinoperator); appendStringInfo(str, " :left_sortop %u ", node->left_sortop); appendStringInfo(str, " :right_sortop %u ", node->right_sortop); appendStringInfo(str, " :hashjoinoperator %u ", node->hashjoinoperator); } /* * JoinInfo is a subclass of Node. */ static void _outJoinInfo(StringInfo str, JoinInfo *node) { appendStringInfo(str, " JINFO :unjoined_relids "); _outIntList(str, node->unjoined_relids); appendStringInfo(str, " :jinfo_restrictinfo "); _outNode(str, node->jinfo_restrictinfo); } /* * Print the value of a Datum given its type. */ static void _outDatum(StringInfo str, Datum value, Oid type) { bool byValue; int typeLength; Size length; char *s; int i; /* * find some information about the type and the "real" length of the * datum. */ byValue = get_typbyval(type); typeLength = get_typlen(type); length = datumGetSize(value, byValue, typeLength); if (byValue) { s = (char *) (&value); appendStringInfo(str, " %u [ ", (unsigned int) length); for (i = 0; i < (int) sizeof(Datum); i++) appendStringInfo(str, "%d ", (int) (s[i])); appendStringInfo(str, "] "); } else { /* !byValue */ s = (char *) DatumGetPointer(value); if (!PointerIsValid(s)) appendStringInfo(str, " 0 [ ] "); else { appendStringInfo(str, " %u [ ", (unsigned int) length); for (i = 0; i < (int) length; i++) appendStringInfo(str, "%d ", (int) (s[i])); appendStringInfo(str, "] "); } } } static void _outIter(StringInfo str, Iter *node) { appendStringInfo(str, " ITER :iterexpr "); _outNode(str, node->iterexpr); } static void _outStream(StringInfo str, Stream *node) { appendStringInfo(str, " STREAM :pathptr @ 0x%x :cinfo @ 0x%x :clausetype %d :upstream @ 0x%x ", (int) node->pathptr, (int) node->cinfo, (int) node->clausetype, (int) node->upstream); appendStringInfo(str, " :downstream @ 0x%x :groupup %d :groupcost %f :groupsel %f ", (int) node->downstream, node->groupup, node->groupcost, node->groupsel); } static void _outAExpr(StringInfo str, A_Expr *node) { appendStringInfo(str, " AEXPR "); switch (node->oper) { case AND: appendStringInfo(str, "AND "); break; case OR: appendStringInfo(str, "OR "); break; case NOT: appendStringInfo(str, "NOT "); break; case ISNULL: appendStringInfo(str, "ISNULL "); break; case NOTNULL: appendStringInfo(str, "NOTNULL "); break; case OP: _outToken(str, node->opname); appendStringInfo(str, " "); break; default: appendStringInfo(str, "?? "); break; } _outNode(str, node->lexpr); appendStringInfo(str, " "); _outNode(str, node->rexpr); } static void _outValue(StringInfo str, Value *value) { switch (value->type) { case T_Integer: appendStringInfo(str, " %ld ", value->val.ival); break; case T_Float: /* * We assume the value is a valid numeric literal and so does * not need quoting. */ appendStringInfo(str, " %s ", value->val.str); break; case T_String: appendStringInfo(str, " \""); _outToken(str, value->val.str); appendStringInfo(str, "\" "); break; default: elog(NOTICE, "_outValue: don't know how to print type %d ", value->type); break; } } static void _outIdent(StringInfo str, Ident *node) { appendStringInfo(str, " IDENT "); _outToken(str, node->name); } static void _outAttr(StringInfo str, Attr *node) { appendStringInfo(str, " ATTR :relname "); _outToken(str, node->relname); appendStringInfo(str, " :attrs "); _outNode(str, node->attrs); } static void _outAConst(StringInfo str, A_Const *node) { appendStringInfo(str, "CONST "); _outValue(str, &(node->val)); appendStringInfo(str, " :typename "); _outNode(str, node->typename); } static void _outConstraint(StringInfo str, Constraint *node) { appendStringInfo(str, " "); _outToken(str, node->name); appendStringInfo(str, " :type "); switch (node->contype) { case CONSTR_PRIMARY: appendStringInfo(str, "PRIMARY KEY "); _outNode(str, node->keys); break; case CONSTR_CHECK: appendStringInfo(str, "CHECK :raw "); _outNode(str, node->raw_expr); appendStringInfo(str, " :cooked "); _outToken(str, node->cooked_expr); break; case CONSTR_DEFAULT: appendStringInfo(str, "DEFAULT :raw "); _outNode(str, node->raw_expr); appendStringInfo(str, " :cooked "); _outToken(str, node->cooked_expr); break; case CONSTR_NOTNULL: appendStringInfo(str, "NOT NULL"); break; case CONSTR_UNIQUE: appendStringInfo(str, "UNIQUE "); _outNode(str, node->keys); break; default: appendStringInfo(str, ""); break; } } static void _outCaseExpr(StringInfo str, CaseExpr *node) { appendStringInfo(str, " CASE :casetype %u :arg ", node->casetype); _outNode(str, node->arg); appendStringInfo(str, " :args "); _outNode(str, node->args); appendStringInfo(str, " :defresult "); _outNode(str, node->defresult); } static void _outCaseWhen(StringInfo str, CaseWhen *node) { appendStringInfo(str, " WHEN "); _outNode(str, node->expr); appendStringInfo(str, " :then "); _outNode(str, node->result); } /* * _outNode - * converts a Node into ascii string and append it to 'str' */ static void _outNode(StringInfo str, void *obj) { if (obj == NULL) { appendStringInfo(str, "<>"); return; } if (IsA(obj, List)) { List *l; appendStringInfoChar(str, '('); foreach(l, (List *) obj) { _outNode(str, lfirst(l)); if (lnext(l)) appendStringInfoChar(str, ' '); } appendStringInfoChar(str, ')'); } else if (IsA_Value(obj)) { /* nodeRead does not want to see { } around these! */ _outValue(str, obj); } else { appendStringInfoChar(str, '{'); switch (nodeTag(obj)) { case T_CreateStmt: _outCreateStmt(str, obj); break; case T_IndexStmt: _outIndexStmt(str, obj); break; case T_ColumnDef: _outColumnDef(str, obj); break; case T_TypeName: _outTypeName(str, obj); break; case T_TypeCast: _outTypeCast(str, obj); break; case T_IndexElem: _outIndexElem(str, obj); break; case T_Query: _outQuery(str, obj); break; case T_SortClause: _outSortClause(str, obj); break; case T_GroupClause: _outGroupClause(str, obj); break; case T_Plan: _outPlan(str, obj); break; case T_Result: _outResult(str, obj); break; case T_Append: _outAppend(str, obj); break; case T_Join: _outJoin(str, obj); break; case T_NestLoop: _outNestLoop(str, obj); break; case T_MergeJoin: _outMergeJoin(str, obj); break; case T_HashJoin: _outHashJoin(str, obj); break; case T_Scan: _outScan(str, obj); break; case T_SeqScan: _outSeqScan(str, obj); break; case T_IndexScan: _outIndexScan(str, obj); break; case T_TidScan: _outTidScan(str, obj); break; case T_Material: _outMaterial(str, obj); break; case T_Sort: _outSort(str, obj); break; case T_Agg: _outAgg(str, obj); break; case T_Group: _outGroup(str, obj); break; case T_Unique: _outUnique(str, obj); break; case T_Hash: _outHash(str, obj); break; case T_SubPlan: _outSubPlan(str, obj); break; case T_Resdom: _outResdom(str, obj); break; case T_Fjoin: _outFjoin(str, obj); break; case T_Expr: _outExpr(str, obj); break; case T_Var: _outVar(str, obj); break; case T_Const: _outConst(str, obj); break; case T_Aggref: _outAggref(str, obj); break; case T_SubLink: _outSubLink(str, obj); break; case T_RelabelType: _outRelabelType(str, obj); break; case T_Array: _outArray(str, obj); break; case T_ArrayRef: _outArrayRef(str, obj); break; case T_Func: _outFunc(str, obj); break; case T_Oper: _outOper(str, obj); break; case T_Param: _outParam(str, obj); break; case T_EState: _outEState(str, obj); break; case T_RelOptInfo: _outRelOptInfo(str, obj); break; case T_IndexOptInfo: _outIndexOptInfo(str, obj); break; case T_TargetEntry: _outTargetEntry(str, obj); break; case T_RangeTblEntry: _outRangeTblEntry(str, obj); break; case T_RowMark: _outRowMark(str, obj); break; case T_Path: _outPath(str, obj); break; case T_IndexPath: _outIndexPath(str, obj); break; case T_TidPath: _outTidPath(str, obj); break; case T_NestPath: _outNestPath(str, obj); break; case T_MergePath: _outMergePath(str, obj); break; case T_HashPath: _outHashPath(str, obj); break; case T_PathKeyItem: _outPathKeyItem(str, obj); break; case T_RestrictInfo: _outRestrictInfo(str, obj); break; case T_JoinInfo: _outJoinInfo(str, obj); break; case T_Iter: _outIter(str, obj); break; case T_Stream: _outStream(str, obj); break; case T_A_Expr: _outAExpr(str, obj); break; case T_Ident: _outIdent(str, obj); break; case T_A_Const: _outAConst(str, obj); break; case T_Constraint: _outConstraint(str, obj); break; case T_CaseExpr: _outCaseExpr(str, obj); break; case T_CaseWhen: _outCaseWhen(str, obj); break; case T_VariableSetStmt: break; case T_SelectStmt: _outSelectStmt(str, obj); break; case T_FuncCall: _outFuncCall(str, obj); break; case T_Attr: _outAttr(str, obj); break; default: elog(NOTICE, "_outNode: don't know how to print type %d ", nodeTag(obj)); break; } appendStringInfoChar(str, '}'); } } /* * nodeToString - * returns the ascii representation of the Node as a palloc'd string */ char * nodeToString(void *obj) { StringInfoData str; /* see stringinfo.h for an explanation of this maneuver */ initStringInfo(&str); _outNode(&str, obj); return str.data; }