/*------------------------------------------------------------------------- * * print.c * various print routines (used mostly for debugging) * * Portions Copyright (c) 1996-2005, PostgreSQL Global Development Group * Portions Copyright (c) 1994, Regents of the University of California * * * IDENTIFICATION * $PostgreSQL: pgsql/src/backend/nodes/print.c,v 1.73 2005/03/16 21:38:08 tgl Exp $ * * HISTORY * AUTHOR DATE MAJOR EVENT * Andrew Yu Oct 26, 1994 file creation * *------------------------------------------------------------------------- */ #include "postgres.h" #include "access/printtup.h" #include "lib/stringinfo.h" #include "nodes/print.h" #include "optimizer/clauses.h" #include "parser/parsetree.h" #include "utils/lsyscache.h" #include "utils/syscache.h" static char *plannode_type(Plan *p); /* * print * print contents of Node to stdout */ void print(void *obj) { char *s; char *f; s = nodeToString(obj); f = format_node_dump(s); pfree(s); printf("%s\n", f); fflush(stdout); pfree(f); } /* * pprint * pretty-print contents of Node to stdout */ void pprint(void *obj) { char *s; char *f; s = nodeToString(obj); f = pretty_format_node_dump(s); pfree(s); printf("%s\n", f); fflush(stdout); pfree(f); } /* * elog_node_display * send pretty-printed contents of Node to postmaster log */ void elog_node_display(int lev, const char *title, void *obj, bool pretty) { char *s; char *f; s = nodeToString(obj); if (pretty) f = pretty_format_node_dump(s); else f = format_node_dump(s); pfree(s); ereport(lev, (errmsg_internal("%s:", title), errdetail("%s", f))); pfree(f); } /* * Format a nodeToString output for display on a terminal. * * The result is a palloc'd string. * * This version just tries to break at whitespace. */ char * format_node_dump(const char *dump) { #define LINELEN 78 char line[LINELEN + 1]; StringInfoData str; int i; int j; int k; initStringInfo(&str); i = 0; for (;;) { for (j = 0; j < LINELEN && dump[i] != '\0'; i++, j++) line[j] = dump[i]; if (dump[i] == '\0') break; if (dump[i] == ' ') { /* ok to break at adjacent space */ i++; } else { for (k = j - 1; k > 0; k--) if (line[k] == ' ') break; if (k > 0) { /* back up; will reprint all after space */ i -= (j - k - 1); j = k; } } line[j] = '\0'; appendStringInfo(&str, "%s\n", line); } if (j > 0) { line[j] = '\0'; appendStringInfo(&str, "%s\n", line); } return str.data; #undef LINELEN } /* * Format a nodeToString output for display on a terminal. * * The result is a palloc'd string. * * This version tries to indent intelligently. */ char * pretty_format_node_dump(const char *dump) { #define INDENTSTOP 3 #define MAXINDENT 60 #define LINELEN 78 char line[LINELEN + 1]; StringInfoData str; int indentLev; int indentDist; int i; int j; initStringInfo(&str); indentLev = 0; /* logical indent level */ indentDist = 0; /* physical indent distance */ i = 0; for (;;) { for (j = 0; j < indentDist; j++) line[j] = ' '; for (; j < LINELEN && dump[i] != '\0'; i++, j++) { line[j] = dump[i]; switch (line[j]) { case '}': if (j != indentDist) { /* print data before the } */ line[j] = '\0'; appendStringInfo(&str, "%s\n", line); } /* print the } at indentDist */ line[indentDist] = '}'; line[indentDist + 1] = '\0'; appendStringInfo(&str, "%s\n", line); /* outdent */ if (indentLev > 0) { indentLev--; indentDist = Min(indentLev * INDENTSTOP, MAXINDENT); } j = indentDist - 1; /* j will equal indentDist on next loop iteration */ /* suppress whitespace just after } */ while (dump[i + 1] == ' ') i++; break; case ')': /* force line break after ), unless another ) follows */ if (dump[i + 1] != ')') { line[j + 1] = '\0'; appendStringInfo(&str, "%s\n", line); j = indentDist - 1; while (dump[i + 1] == ' ') i++; } break; case '{': /* force line break before { */ if (j != indentDist) { line[j] = '\0'; appendStringInfo(&str, "%s\n", line); } /* indent */ indentLev++; indentDist = Min(indentLev * INDENTSTOP, MAXINDENT); for (j = 0; j < indentDist; j++) line[j] = ' '; line[j] = dump[i]; break; case ':': /* force line break before : */ if (j != indentDist) { line[j] = '\0'; appendStringInfo(&str, "%s\n", line); } j = indentDist; line[j] = dump[i]; break; } } line[j] = '\0'; if (dump[i] == '\0') break; appendStringInfo(&str, "%s\n", line); } if (j > 0) appendStringInfo(&str, "%s\n", line); return str.data; #undef INDENTSTOP #undef MAXINDENT #undef LINELEN } /* * print_rt * print contents of range table */ void print_rt(List *rtable) { ListCell *l; int i = 1; printf("resno\trefname \trelid\tinFromCl\n"); printf("-----\t---------\t-----\t--------\n"); foreach(l, rtable) { RangeTblEntry *rte = lfirst(l); switch (rte->rtekind) { case RTE_RELATION: printf("%d\t%s\t%u", i, rte->eref->aliasname, rte->relid); break; case RTE_SUBQUERY: printf("%d\t%s\t[subquery]", i, rte->eref->aliasname); break; case RTE_FUNCTION: printf("%d\t%s\t[rangefunction]", i, rte->eref->aliasname); break; case RTE_JOIN: printf("%d\t%s\t[join]", i, rte->eref->aliasname); break; case RTE_SPECIAL: printf("%d\t%s\t[special]", i, rte->eref->aliasname); break; default: printf("%d\t%s\t[unknown rtekind]", i, rte->eref->aliasname); } printf("\t%s\t%s\n", (rte->inh ? "inh" : ""), (rte->inFromCl ? "inFromCl" : "")); i++; } } /* * print_expr * print an expression */ void print_expr(Node *expr, List *rtable) { if (expr == NULL) { printf("<>"); return; } if (IsA(expr, Var)) { Var *var = (Var *) expr; char *relname, *attname; switch (var->varno) { case INNER: relname = "INNER"; attname = "?"; break; case OUTER: relname = "OUTER"; attname = "?"; break; default: { RangeTblEntry *rte; Assert(var->varno > 0 && (int) var->varno <= list_length(rtable)); rte = rt_fetch(var->varno, rtable); relname = rte->eref->aliasname; attname = get_rte_attribute_name(rte, var->varattno); } break; } printf("%s.%s", relname, attname); } else if (IsA(expr, Const)) { Const *c = (Const *) expr; Oid typoutput; Oid typioparam; bool typIsVarlena; char *outputstr; if (c->constisnull) { printf("NULL"); return; } getTypeOutputInfo(c->consttype, &typoutput, &typioparam, &typIsVarlena); outputstr = DatumGetCString(OidFunctionCall3(typoutput, c->constvalue, ObjectIdGetDatum(typioparam), Int32GetDatum(-1))); printf("%s", outputstr); pfree(outputstr); } else if (IsA(expr, OpExpr)) { OpExpr *e = (OpExpr *) expr; char *opname; opname = get_opname(e->opno); if (list_length(e->args) > 1) { print_expr(get_leftop((Expr *) e), rtable); printf(" %s ", ((opname != NULL) ? opname : "(invalid operator)")); print_expr(get_rightop((Expr *) e), rtable); } else { /* we print prefix and postfix ops the same... */ printf("%s ", ((opname != NULL) ? opname : "(invalid operator)")); print_expr(get_leftop((Expr *) e), rtable); } } else if (IsA(expr, FuncExpr)) { FuncExpr *e = (FuncExpr *) expr; char *funcname; ListCell *l; funcname = get_func_name(e->funcid); printf("%s(", ((funcname != NULL) ? funcname : "(invalid function)")); foreach(l, e->args) { print_expr(lfirst(l), rtable); if (lnext(l)) printf(","); } printf(")"); } else printf("unknown expr"); } /* * print_pathkeys - * pathkeys list of list of PathKeyItems */ void print_pathkeys(List *pathkeys, List *rtable) { ListCell *i; printf("("); foreach(i, pathkeys) { List *pathkey = (List *) lfirst(i); ListCell *k; printf("("); foreach(k, pathkey) { PathKeyItem *item = (PathKeyItem *) lfirst(k); print_expr(item->key, rtable); if (lnext(k)) printf(", "); } printf(")"); if (lnext(i)) printf(", "); } printf(")\n"); } /* * print_tl * print targetlist in a more legible way. */ void print_tl(List *tlist, List *rtable) { ListCell *tl; printf("(\n"); foreach(tl, tlist) { TargetEntry *tle = (TargetEntry *) lfirst(tl); printf("\t%d %s\t", tle->resdom->resno, tle->resdom->resname ? tle->resdom->resname : ""); if (tle->resdom->ressortgroupref != 0) printf("(%u):\t", tle->resdom->ressortgroupref); else printf(" :\t"); print_expr((Node *) tle->expr, rtable); printf("\n"); } printf(")\n"); } /* * print_slot * print out the tuple with the given TupleTableSlot */ void print_slot(TupleTableSlot *slot) { if (TupIsNull(slot)) { printf("tuple is null.\n"); return; } if (!slot->tts_tupleDescriptor) { printf("no tuple descriptor.\n"); return; } debugtup(slot, NULL); } static char * plannode_type(Plan *p) { switch (nodeTag(p)) { case T_Plan: return "PLAN"; case T_Result: return "RESULT"; case T_Append: return "APPEND"; case T_Scan: return "SCAN"; case T_SeqScan: return "SEQSCAN"; case T_IndexScan: return "INDEXSCAN"; case T_TidScan: return "TIDSCAN"; case T_SubqueryScan: return "SUBQUERYSCAN"; case T_FunctionScan: return "FUNCTIONSCAN"; case T_Join: return "JOIN"; case T_NestLoop: return "NESTLOOP"; case T_MergeJoin: return "MERGEJOIN"; case T_HashJoin: return "HASHJOIN"; case T_Material: return "MATERIAL"; case T_Sort: return "SORT"; case T_Agg: return "AGG"; case T_Unique: return "UNIQUE"; case T_SetOp: return "SETOP"; case T_Limit: return "LIMIT"; case T_Hash: return "HASH"; case T_Group: return "GROUP"; default: return "UNKNOWN"; } } /* * Recursively prints a simple text description of the plan tree */ void print_plan_recursive(Plan *p, Query *parsetree, int indentLevel, char *label) { int i; char extraInfo[NAMEDATALEN + 100]; if (!p) return; for (i = 0; i < indentLevel; i++) printf(" "); printf("%s%s :c=%.2f..%.2f :r=%.0f :w=%d ", label, plannode_type(p), p->startup_cost, p->total_cost, p->plan_rows, p->plan_width); if (IsA(p, Scan) || IsA(p, SeqScan)) { RangeTblEntry *rte; rte = rt_fetch(((Scan *) p)->scanrelid, parsetree->rtable); StrNCpy(extraInfo, rte->eref->aliasname, NAMEDATALEN); } else if (IsA(p, IndexScan)) { RangeTblEntry *rte; rte = rt_fetch(((IndexScan *) p)->scan.scanrelid, parsetree->rtable); StrNCpy(extraInfo, rte->eref->aliasname, NAMEDATALEN); } else if (IsA(p, FunctionScan)) { RangeTblEntry *rte; rte = rt_fetch(((FunctionScan *) p)->scan.scanrelid, parsetree->rtable); StrNCpy(extraInfo, rte->eref->aliasname, NAMEDATALEN); } else extraInfo[0] = '\0'; if (extraInfo[0] != '\0') printf(" ( %s )\n", extraInfo); else printf("\n"); print_plan_recursive(p->lefttree, parsetree, indentLevel + 3, "l: "); print_plan_recursive(p->righttree, parsetree, indentLevel + 3, "r: "); if (IsA(p, Append)) { ListCell *l; int whichplan = 0; Append *appendplan = (Append *) p; foreach(l, appendplan->appendplans) { Plan *subnode = (Plan *) lfirst(l); /* * I don't think we need to fiddle with the range table here, * bjm */ print_plan_recursive(subnode, parsetree, indentLevel + 3, "a: "); whichplan++; } } } /* print_plan prints just the plan node types */ void print_plan(Plan *p, Query *parsetree) { print_plan_recursive(p, parsetree, 0, ""); }