/* * $Header: /cvsroot/pgsql/src/test/regress/regress.c,v 1.39 2000/06/11 20:07:44 tgl Exp $ */ #include /* faked on sunos */ #include "postgres.h" #include "utils/geo_decls.h" /* includes */ #include "executor/executor.h" /* For GetAttributeByName */ #include "commands/sequence.h" /* for nextval() */ #define P_MAXDIG 12 #define LDELIM '(' #define RDELIM ')' #define DELIM ',' typedef TupleTableSlot *TUPLE; extern double *regress_dist_ptpath(Point *pt, PATH *path); extern double *regress_path_dist(PATH *p1, PATH *p2); extern PATH *poly2path(POLYGON *poly); extern Point *interpt_pp(PATH *p1, PATH *p2); extern void regress_lseg_construct(LSEG *lseg, Point *pt1, Point *pt2); extern Datum overpaid(PG_FUNCTION_ARGS); extern int boxarea(BOX *box); extern char *reverse_name(char *string); /* ** Distance from a point to a path */ double * regress_dist_ptpath(pt, path) Point *pt; PATH *path; { double *result; double *tmp; int i; LSEG lseg; switch (path->npts) { case 0: result = palloc(sizeof(double)); *result = Abs((double) DBL_MAX); /* +infinity */ break; case 1: result = point_distance(pt, &path->p[0]); break; default: /* * the distance from a point to a path is the smallest * distance from the point to any of its constituent segments. */ Assert(path->npts > 1); result = palloc(sizeof(double)); for (i = 0; i < path->npts - 1; ++i) { regress_lseg_construct(&lseg, &path->p[i], &path->p[i + 1]); tmp = dist_ps(pt, &lseg); if (i == 0 || *tmp < *result) *result = *tmp; pfree(tmp); } break; } return result; } /* this essentially does a cartesian product of the lsegs in the two paths, and finds the min distance between any two lsegs */ double * regress_path_dist(p1, p2) PATH *p1; PATH *p2; { double *min, *tmp; int i, j; LSEG seg1, seg2; regress_lseg_construct(&seg1, &p1->p[0], &p1->p[1]); regress_lseg_construct(&seg2, &p2->p[0], &p2->p[1]); min = lseg_distance(&seg1, &seg2); for (i = 0; i < p1->npts - 1; i++) for (j = 0; j < p2->npts - 1; j++) { regress_lseg_construct(&seg1, &p1->p[i], &p1->p[i + 1]); regress_lseg_construct(&seg2, &p2->p[j], &p2->p[j + 1]); if (*min < *(tmp = lseg_distance(&seg1, &seg2))) *min = *tmp; pfree(tmp); } return min; } PATH * poly2path(poly) POLYGON *poly; { int i; char *output = (char *) palloc(2 * (P_MAXDIG + 1) * poly->npts + 64); char buf[2 * (P_MAXDIG) + 20]; sprintf(output, "(1, %*d", P_MAXDIG, poly->npts); for (i = 0; i < poly->npts; i++) { sprintf(buf, ",%*g,%*g", P_MAXDIG, poly->p[i].x, P_MAXDIG, poly->p[i].y); strcat(output, buf); } sprintf(buf, "%c", RDELIM); strcat(output, buf); return path_in(output); } /* return the point where two paths intersect. Assumes that they do. */ Point * interpt_pp(p1, p2) PATH *p1; PATH *p2; { Point *retval; int i, j; LSEG seg1, seg2; #ifdef NOT_USED LINE *ln; #endif bool found; /* We've found the intersection */ found = false; /* Haven't found it yet */ for (i = 0; i < p1->npts - 1 && !found; i++) for (j = 0; j < p2->npts - 1 && !found; j++) { regress_lseg_construct(&seg1, &p1->p[i], &p1->p[i + 1]); regress_lseg_construct(&seg2, &p2->p[j], &p2->p[j + 1]); if (lseg_intersect(&seg1, &seg2)) found = true; } #ifdef NOT_USED ln = line_construct_pp(&seg2.p[0], &seg2.p[1]); retval = interpt_sl(&seg1, ln); #endif retval = lseg_interpt(&seg1, &seg2); return retval; } /* like lseg_construct, but assume space already allocated */ void regress_lseg_construct(lseg, pt1, pt2) LSEG *lseg; Point *pt1; Point *pt2; { lseg->p[0].x = pt1->x; lseg->p[0].y = pt1->y; lseg->p[1].x = pt2->x; lseg->p[1].y = pt2->y; lseg->m = point_sl(pt1, pt2); } Datum overpaid(PG_FUNCTION_ARGS) { TUPLE tuple = (TUPLE) PG_GETARG_POINTER(0); bool isnull; long salary; salary = (long) GetAttributeByName(tuple, "salary", &isnull); if (isnull) PG_RETURN_NULL(); PG_RETURN_BOOL(salary > 699); } /* New type "widget" * This used to be "circle", but I added circle to builtins, * so needed to make sure the names do not collide. - tgl 97/04/21 */ typedef struct { Point center; double radius; } WIDGET; WIDGET *widget_in(char *str); char *widget_out(WIDGET * widget); int pt_in_widget(Point *point, WIDGET * widget); #define NARGS 3 WIDGET * widget_in(str) char *str; { char *p, *coord[NARGS], buf2[1000]; int i; WIDGET *result; if (str == NULL) return NULL; for (i = 0, p = str; *p && i < NARGS && *p != RDELIM; p++) if (*p == ',' || (*p == LDELIM && !i)) coord[i++] = p + 1; if (i < NARGS - 1) return NULL; result = (WIDGET *) palloc(sizeof(WIDGET)); result->center.x = atof(coord[0]); result->center.y = atof(coord[1]); result->radius = atof(coord[2]); sprintf(buf2, "widget_in: read (%f, %f, %f)\n", result->center.x, result->center.y, result->radius); return result; } char * widget_out(widget) WIDGET *widget; { char *result; if (widget == NULL) return NULL; result = (char *) palloc(60); sprintf(result, "(%g,%g,%g)", widget->center.x, widget->center.y, widget->radius); return result; } int pt_in_widget(point, widget) Point *point; WIDGET *widget; { extern double point_dt(); return point_dt(point, &widget->center) < widget->radius; } #define ABS(X) ((X) > 0 ? (X) : -(X)) int boxarea(box) BOX *box; { int width, height; width = ABS(box->high.x - box->low.x); height = ABS(box->high.y - box->low.y); return width * height; } char * reverse_name(string) char *string; { int i; int len; char *new_string; if (!(new_string = palloc(NAMEDATALEN))) { fprintf(stderr, "reverse_name: palloc failed\n"); return NULL; } MemSet(new_string, 0, NAMEDATALEN); for (i = 0; i < NAMEDATALEN && string[i]; ++i) ; if (i == NAMEDATALEN || !string[i]) --i; len = i; for (; i >= 0; --i) new_string[len - i] = string[i]; return new_string; } #include "executor/spi.h" /* this is what you need to work with SPI */ #include "commands/trigger.h" /* -"- and triggers */ static TransactionId fd17b_xid = InvalidTransactionId; static TransactionId fd17a_xid = InvalidTransactionId; static int fd17b_level = 0; static int fd17a_level = 0; static bool fd17b_recursion = true; static bool fd17a_recursion = true; extern Datum funny_dup17(PG_FUNCTION_ARGS); Datum funny_dup17(PG_FUNCTION_ARGS) { TriggerData *trigdata = (TriggerData *) fcinfo->context; TransactionId *xid; int *level; bool *recursion; Relation rel; TupleDesc tupdesc; HeapTuple tuple; char *query, *fieldval, *fieldtype; char *when; int inserted; int selected = 0; int ret; if (!CALLED_AS_TRIGGER(fcinfo)) elog(ERROR, "funny_dup17: not fired by trigger manager"); tuple = trigdata->tg_trigtuple; rel = trigdata->tg_relation; tupdesc = rel->rd_att; if (TRIGGER_FIRED_BEFORE(trigdata->tg_event)) { xid = &fd17b_xid; level = &fd17b_level; recursion = &fd17b_recursion; when = "BEFORE"; } else { xid = &fd17a_xid; level = &fd17a_level; recursion = &fd17a_recursion; when = "AFTER "; } if (!TransactionIdIsCurrentTransactionId(*xid)) { *xid = GetCurrentTransactionId(); *level = 0; *recursion = true; } if (*level == 17) { *recursion = false; return PointerGetDatum(tuple); } if (!(*recursion)) return PointerGetDatum(tuple); (*level)++; SPI_connect(); fieldval = SPI_getvalue(tuple, tupdesc, 1); fieldtype = SPI_gettype(tupdesc, 1); query = (char *) palloc(100 + NAMEDATALEN * 3 + strlen(fieldval) + strlen(fieldtype)); sprintf(query, "insert into %s select * from %s where %s = '%s'::%s", SPI_getrelname(rel), SPI_getrelname(rel), SPI_fname(tupdesc, 1), fieldval, fieldtype); if ((ret = SPI_exec(query, 0)) < 0) elog(ERROR, "funny_dup17 (fired %s) on level %3d: SPI_exec (insert ...) returned %d", when, *level, ret); inserted = SPI_processed; sprintf(query, "select count (*) from %s where %s = '%s'::%s", SPI_getrelname(rel), SPI_fname(tupdesc, 1), fieldval, fieldtype); if ((ret = SPI_exec(query, 0)) < 0) elog(ERROR, "funny_dup17 (fired %s) on level %3d: SPI_exec (select ...) returned %d", when, *level, ret); if (SPI_processed > 0) { selected = DatumGetInt32(DirectFunctionCall1(int4in, CStringGetDatum(SPI_getvalue( SPI_tuptable->vals[0], SPI_tuptable->tupdesc, 1 )))); } elog(NOTICE, "funny_dup17 (fired %s) on level %3d: %d/%d tuples inserted/selected", when, *level, inserted, selected); SPI_finish(); (*level)--; if (*level == 0) *xid = InvalidTransactionId; return PointerGetDatum(tuple); } extern Datum ttdummy(PG_FUNCTION_ARGS); int32 set_ttdummy(int32 on); #define TTDUMMY_INFINITY 999999 static void *splan = NULL; static bool ttoff = false; Datum ttdummy(PG_FUNCTION_ARGS) { TriggerData *trigdata = (TriggerData *) fcinfo->context; Trigger *trigger; /* to get trigger name */ char **args; /* arguments */ int attnum[2]; /* fnumbers of start/stop columns */ Datum oldon, oldoff; Datum newon, newoff; Datum *cvals; /* column values */ char *cnulls; /* column nulls */ char *relname; /* triggered relation name */ Relation rel; /* triggered relation */ HeapTuple trigtuple; HeapTuple newtuple = NULL; HeapTuple rettuple; TupleDesc tupdesc; /* tuple description */ int natts; /* # of attributes */ bool isnull; /* to know is some column NULL or not */ int ret; int i; if (!CALLED_AS_TRIGGER(fcinfo)) elog(ERROR, "ttdummy: not fired by trigger manager"); if (TRIGGER_FIRED_FOR_STATEMENT(trigdata->tg_event)) elog(ERROR, "ttdummy: can't process STATEMENT events"); if (TRIGGER_FIRED_AFTER(trigdata->tg_event)) elog(ERROR, "ttdummy: must be fired before event"); if (TRIGGER_FIRED_BY_INSERT(trigdata->tg_event)) elog(ERROR, "ttdummy: can't process INSERT event"); if (TRIGGER_FIRED_BY_UPDATE(trigdata->tg_event)) newtuple = trigdata->tg_newtuple; trigtuple = trigdata->tg_trigtuple; rel = trigdata->tg_relation; relname = SPI_getrelname(rel); /* check if TT is OFF for this relation */ if (ttoff) /* OFF - nothing to do */ { pfree(relname); return PointerGetDatum((newtuple != NULL) ? newtuple : trigtuple); } trigger = trigdata->tg_trigger; if (trigger->tgnargs != 2) elog(ERROR, "ttdummy (%s): invalid (!= 2) number of arguments %d", relname, trigger->tgnargs); args = trigger->tgargs; tupdesc = rel->rd_att; natts = tupdesc->natts; for (i = 0; i < 2; i++) { attnum[i] = SPI_fnumber(tupdesc, args[i]); if (attnum[i] < 0) elog(ERROR, "ttdummy (%s): there is no attribute %s", relname, args[i]); if (SPI_gettypeid(tupdesc, attnum[i]) != INT4OID) elog(ERROR, "ttdummy (%s): attributes %s and %s must be of abstime type", relname, args[0], args[1]); } oldon = SPI_getbinval(trigtuple, tupdesc, attnum[0], &isnull); if (isnull) elog(ERROR, "ttdummy (%s): %s must be NOT NULL", relname, args[0]); oldoff = SPI_getbinval(trigtuple, tupdesc, attnum[1], &isnull); if (isnull) elog(ERROR, "ttdummy (%s): %s must be NOT NULL", relname, args[1]); if (newtuple != NULL) /* UPDATE */ { newon = SPI_getbinval(newtuple, tupdesc, attnum[0], &isnull); if (isnull) elog(ERROR, "ttdummy (%s): %s must be NOT NULL", relname, args[0]); newoff = SPI_getbinval(newtuple, tupdesc, attnum[1], &isnull); if (isnull) elog(ERROR, "ttdummy (%s): %s must be NOT NULL", relname, args[1]); if (oldon != newon || oldoff != newoff) elog(ERROR, "ttdummy (%s): you can't change %s and/or %s columns (use set_ttdummy)", relname, args[0], args[1]); if (newoff != TTDUMMY_INFINITY) { pfree(relname); /* allocated in upper executor context */ return PointerGetDatum(NULL); } } else if (oldoff != TTDUMMY_INFINITY) /* DELETE */ { pfree(relname); return PointerGetDatum(NULL); } { text *seqname = textin("ttdummy_seq"); newoff = DirectFunctionCall1(nextval, PointerGetDatum(seqname)); pfree(seqname); } /* Connect to SPI manager */ if ((ret = SPI_connect()) < 0) elog(ERROR, "ttdummy (%s): SPI_connect returned %d", relname, ret); /* Fetch tuple values and nulls */ cvals = (Datum *) palloc(natts * sizeof(Datum)); cnulls = (char *) palloc(natts * sizeof(char)); for (i = 0; i < natts; i++) { cvals[i] = SPI_getbinval((newtuple != NULL) ? newtuple : trigtuple, tupdesc, i + 1, &isnull); cnulls[i] = (isnull) ? 'n' : ' '; } /* change date column(s) */ if (newtuple) /* UPDATE */ { cvals[attnum[0] - 1] = newoff; /* start_date eq current date */ cnulls[attnum[0] - 1] = ' '; cvals[attnum[1] - 1] = TTDUMMY_INFINITY; /* stop_date eq INFINITY */ cnulls[attnum[1] - 1] = ' '; } else /* DELETE */ { cvals[attnum[1] - 1] = newoff; /* stop_date eq current date */ cnulls[attnum[1] - 1] = ' '; } /* if there is no plan ... */ if (splan == NULL) { void *pplan; Oid *ctypes; char *query; /* allocate space in preparation */ ctypes = (Oid *) palloc(natts * sizeof(Oid)); query = (char *) palloc(100 + 16 * natts); /* * Construct query: INSERT INTO _relation_ VALUES ($1, ...) */ sprintf(query, "INSERT INTO %s VALUES (", relname); for (i = 1; i <= natts; i++) { sprintf(query + strlen(query), "$%d%s", i, (i < natts) ? ", " : ")"); ctypes[i - 1] = SPI_gettypeid(tupdesc, i); } /* Prepare plan for query */ pplan = SPI_prepare(query, natts, ctypes); if (pplan == NULL) elog(ERROR, "ttdummy (%s): SPI_prepare returned %d", relname, SPI_result); pplan = SPI_saveplan(pplan); if (pplan == NULL) elog(ERROR, "ttdummy (%s): SPI_saveplan returned %d", relname, SPI_result); splan = pplan; } ret = SPI_execp(splan, cvals, cnulls, 0); if (ret < 0) elog(ERROR, "ttdummy (%s): SPI_execp returned %d", relname, ret); /* Tuple to return to upper Executor ... */ if (newtuple) /* UPDATE */ { HeapTuple tmptuple; tmptuple = SPI_copytuple(trigtuple); rettuple = SPI_modifytuple(rel, tmptuple, 1, &(attnum[1]), &newoff, NULL); SPI_freetuple(tmptuple); } else /* DELETE */ rettuple = trigtuple; SPI_finish(); /* don't forget say Bye to SPI mgr */ pfree(relname); return PointerGetDatum(rettuple); } int32 set_ttdummy(int32 on) { if (ttoff) /* OFF currently */ { if (on == 0) return 0; /* turn ON */ ttoff = false; return 0; } /* ON currently */ if (on != 0) return 1; /* turn OFF */ ttoff = true; return 1; }