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Source:NetHack 2.3e/mklev.c

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Below is the full text to mklev.c from the source code of NetHack 2.3e. To link to a particular line, write [[NetHack 2.3e/mklev.c#line123]], for example.

Warning! This is the source code from an old release. For the latest release, see Source code

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1.    /*	SCCS Id: @(#)mklev.c	2.3	87/12/12
2.    /* Copyright (c) Stichting Mathematisch Centrum, Amsterdam, 1985. */
3.    
4.    #include "hack.h"
5.    
6.    extern char *getlogin(), *getenv();
7.    extern struct monst *makemon(), *mkmon_at();
8.    extern struct obj *mkobj_at(), *mksobj_at();
9.    extern struct trap *maketrap();
10.   
11.   #ifdef RPH
12.   extern struct permonst pm_medusa;
13.   #endif
14.   
15.   #ifdef STOOGES
16.   extern struct permonst pm_larry, pm_curly, pm_moe;
17.   #endif
18.   
19.   #define somex() ((int)(rand()%(croom->hx-croom->lx+1))+croom->lx)
20.   #define somey() ((int)(rand()%(croom->hy-croom->ly+1))+croom->ly)
21.   
22.   #include "mkroom.h"
23.   #define	XLIM	4	/* define minimum required space around a room */
24.   #define	YLIM	3
25.   boolean secret;		/* TRUE while making a vault: increase [XY]LIM */
26.   extern struct mkroom rooms[MAXNROFROOMS+1];
27.   int smeq[MAXNROFROOMS+1];
28.   extern coord doors[DOORMAX];
29.   int doorindex;
30.   struct rm zerorm;
31.   int comp();
32.   schar nxcor;
33.   boolean goldseen;
34.   int nroom;
35.   extern xchar xdnstair,xupstair,ydnstair,yupstair;
36.   
37.   /* Definitions used by makerooms() and addrs() */
38.   #define	MAXRS	50	/* max lth of temp rectangle table - arbitrary */
39.   struct rectangle {
40.   	xchar rlx,rly,rhx,rhy;
41.   } rs[MAXRS+1];
42.   int rscnt,rsmax;	/* 0..rscnt-1: currently under consideration */
43.   			/* rscnt..rsmax: discarded */
44.   
45.   makelevel()
46.   {
47.   	register struct mkroom *croom, *troom;
48.   	register unsigned tryct;
49.   #ifndef REGBUG
50.   	register
51.   #endif
52.   		 int x,y;
53.   #ifdef SPIDERS			/* always put a web with a spider */
54.   	struct monst *tmonst;
55.   #endif
56.   
57.   	nroom = 0;
58.   	doorindex = 0;
59.   	rooms[0].hx = -1;	/* in case we are in a maze */
60.   
61.   	for(x=0; x<COLNO; x++) for(y=0; y<ROWNO; y++)
62.   		levl[x][y] = zerorm;
63.   
64.   	oinit();	/* assign level dependent obj probabilities */
65.   #ifdef RPH
66.   	if (u.wiz_level == 0) {
67.   	    u.medusa_level = rn1(3, (MAXLEVEL > 30) ? 25 : (MAXLEVEL - 4) ); 
68.   	    u.wiz_level    = rn1(MAXLEVEL-u.medusa_level, u.medusa_level)+1;
69.   #ifdef STOOGES
70.   	    u.stooge_level = rn1(6,4);
71.   #endif
72.   	}
73.   	if (dlevel > u.medusa_level) {
74.   	    makemaz();
75.   	    return;
76.   	}
77.   #else
78.   	if(dlevel >= rn1(3, 26)) {	/* there might be several mazes */
79.   		makemaz();
80.   		return;
81.   	}
82.   #endif
83.   	/* construct the rooms */
84.   	nroom = 0;
85.   	secret = FALSE;
86.   	(void) makerooms();
87.   
88.   	/* construct stairs (up and down in different rooms if possible) */
89.   	croom = &rooms[rn2(nroom)];
90.   	xdnstair = somex();
91.   	ydnstair = somey();
92.   	levl[xdnstair][ydnstair].scrsym = DN_SYM;
93.   	levl[xdnstair][ydnstair].typ = STAIRS;
94.   #ifdef RPH
95.   	{ struct monst *mtmp;
96.   	if (dlevel == u.medusa_level) 
97.   	    if (mtmp = makemon(PM_MEDUSA, xdnstair, ydnstair))
98.   	        mtmp->msleep = 1;
99.   	}
100.  #endif
101.  #ifdef STOOGES
102.  	{ struct monst *mtmp;
103.  	if (dlevel == u.stooge_level) {    /* probably should use enexto */
104.  		mtmp = makemon(PM_MOE, xdnstair, ydnstair);
105.  		if (mtmp) mtmp->isstooge = 1;
106.  		if (mtmp) mtmp->mpeaceful = 1;
107.  		if (goodpos(xdnstair+1, ydnstair))
108.  	    		mtmp = makemon(PM_LARRY, xdnstair+1, ydnstair);
109.  		else if (goodpos(xdnstair-1, ydnstair))
110.  	    		mtmp = makemon(PM_LARRY, xdnstair-1, ydnstair);
111.  		if (mtmp) mtmp->isstooge = 1;
112.  		if (mtmp) mtmp->mpeaceful = 1;
113.  		if (goodpos(xdnstair, ydnstair+1))
114.  	    		mtmp = makemon(PM_CURLY, xdnstair, ydnstair+1);
115.  	    	else if (goodpos(xdnstair, ydnstair-1))
116.  	    		mtmp = makemon(PM_CURLY, xdnstair, ydnstair-1);
117.  		if (mtmp) mtmp->isstooge = 1;
118.  		if (mtmp) mtmp->mpeaceful = 1;
119.  	 	}
120.  	}
121.  #endif
122.  	if(nroom > 1) {
123.  		troom = croom;
124.  		croom = &rooms[rn2(nroom-1)];
125.  		if(croom >= troom) croom++;
126.  	}
127.  	xupstair = somex();	/* %% < and > might be in the same place */
128.  	yupstair = somey();
129.  	levl[xupstair][yupstair].scrsym = UP_SYM;
130.  	levl[xupstair][yupstair].typ = STAIRS;
131.  
132.  	/* for each room: put things inside */
133.  	for(croom = rooms; croom->hx > 0; croom++) {
134.  
135.  		/* put a sleeping monster inside */
136.  		/* Note: monster may be on the stairs. This cannot be
137.  		   avoided: maybe the player fell through a trapdoor
138.  		   while a monster was on the stairs. Conclusion:
139.  		   we have to check for monsters on the stairs anyway. */
140.  #ifdef BVH
141.  		if(has_amulet() || !rn2(3))
142.  #else
143.  		if (!rn2(3))
144.  #endif
145.  #ifndef SPIDERS
146.  		    (void)makemon((struct permonst *) 0, somex(), somey());
147.  #else
148.  		{
149.  		    x = somex(); y = somey();
150.  		    tmonst=makemon((struct permonst *) 0, x,y);
151.  		    if (tmonst && tmonst->data->mlet == 's')
152.  		        (void) maketrap (x,y,WEB);
153.  		}
154.  #endif
155.  		/* put traps and mimics inside */
156.  		goldseen = FALSE;
157.  		while(!rn2(8-(dlevel/6))) mktrap(0,0,croom);
158.  		if(!goldseen && !rn2(3)) mkgold(0L,somex(),somey());
159.  #ifdef FOUNTAINS
160.  		if(!rn2(10)) mkfount(0,croom);
161.  #endif
162.  #ifdef SINKS
163.  		if(!rn2(80)) mksink(croom);
164.  #endif
165.  		if(!rn2(3)) {
166.  			(void) mkobj_at(0, somex(), somey());
167.  			tryct = 0;
168.  			while(!rn2(5)) {
169.  				if(++tryct > 100){
170.  					printf("tryct overflow4\n");
171.  					break;
172.  				}
173.  				(void) mkobj_at(0, somex(), somey());
174.  			}
175.  		}
176.  	}
177.  
178.  	qsort((char *) rooms, nroom, sizeof(struct mkroom), comp);
179.  	makecorridors();
180.  	make_niches();
181.  
182.  	/* make a secret treasure vault, not connected to the rest */
183.  	if(nroom <= (2*MAXNROFROOMS/3)) if(rn2(3)) {
184.  		troom = &rooms[nroom];
185.  		secret = TRUE;
186.  		if(makerooms()) {
187.  			troom->rtype = VAULT;		/* treasure vault */
188.  			for(x = troom->lx; x <= troom->hx; x++)
189.  			for(y = troom->ly; y <= troom->hy; y++)
190.  				mkgold((long)(rnd(dlevel*100) + 50), x, y);
191.  			if(!rn2(3))
192.  				makevtele();
193.  		}
194.  	}
195.  
196.  #ifdef WIZARD
197.  	if(wizard && getenv("SHOPTYPE")) mkroom(SHOPBASE); else
198.  #endif
199.  	if(dlevel > 1 && dlevel < 20 && rn2(dlevel) < 3) mkroom(SHOPBASE);
200.  	else
201.  #ifdef NEWCLASS
202.  	if(dlevel > 4 && !rn2(6)) mkroom(COURT);
203.  	else
204.  #endif
205.  	if(dlevel > 6 && !rn2(7)) mkroom(ZOO);
206.  	else
207.  	if(dlevel > 9 && !rn2(5)) mkroom(BEEHIVE);
208.  	else
209.  	if(dlevel > 11 && !rn2(6)) mkroom(MORGUE);
210.  	else
211.  #ifdef SAC
212.  	if(dlevel > 14 && !rn2(4)) mkroom(BARRACKS);
213.  	else
214.  #endif
215.  	if(dlevel > 18 && !rn2(6)) mkroom(SWAMP);
216.  }
217.  
218.  makerooms() {
219.  register struct rectangle *rsp;
220.  register int lx, ly, hx, hy, lowx, lowy, hix, hiy, dx, dy;
221.  int tryct = 0, xlim, ylim;
222.  
223.  	/* init */
224.  	xlim = XLIM + secret;
225.  	ylim = YLIM + secret;
226.  	if(nroom == 0) {
227.  		rsp = rs;
228.  		rsp->rlx = rsp->rly = 0;
229.  		rsp->rhx = COLNO-1;
230.  		rsp->rhy = ROWNO-1;
231.  		rsmax = 1;
232.  	}
233.  	rscnt = rsmax;
234.  
235.  	/* make rooms until satisfied */
236.  	while(rscnt > 0 && nroom < MAXNROFROOMS-1) {
237.  		if(!secret && nroom > (MAXNROFROOMS/3) &&
238.  		   !rn2((MAXNROFROOMS-nroom)*(MAXNROFROOMS-nroom)))
239.  			return(0);
240.  
241.  		/* pick a rectangle */
242.  		rsp = &rs[rn2(rscnt)];
243.  		hx = rsp->rhx;
244.  		hy = rsp->rhy;
245.  		lx = rsp->rlx;
246.  		ly = rsp->rly;
247.  
248.  		/* find size of room */
249.  		if(secret)
250.  			dx = dy = 1;
251.  		else {
252.  			dx = 2 + rn2((hx-lx-8 > 20) ? 12 : 8);
253.  			dy = 2 + rn2(4);
254.  			if(dx*dy > 50)
255.  				dy = 50/dx;
256.  		}
257.  
258.  		/* look whether our room will fit */
259.  		if(hx-lx < dx + dx/2 + 2*xlim || hy-ly < dy + dy/3 + 2*ylim) {
260.  					/* no, too small */
261.  					/* maybe we throw this area out */
262.  			if(secret || !rn2(MAXNROFROOMS+1-nroom-tryct)) {
263.  				rscnt--;
264.  				rs[rsmax] = *rsp;
265.  				*rsp = rs[rscnt];
266.  				rs[rscnt] = rs[rsmax];
267.  				tryct = 0;
268.  			} else
269.  				tryct++;
270.  			continue;
271.  		}
272.  
273.  		lowx = lx + xlim + rn2(hx - lx - dx - 2*xlim + 1);
274.  		lowy = ly + ylim + rn2(hy - ly - dy - 2*ylim + 1);
275.  		hix = lowx + dx;
276.  		hiy = lowy + dy;
277.  
278.  		if(maker(lowx, dx, lowy, dy)) {
279.  			if(secret) return(1);
280.  			addrs(lowx-1, lowy-1, hix+1, hiy+1);
281.  			tryct = 0;
282.  		} else
283.  			if(tryct++ > 100)
284.  				break;
285.  	}
286.  	return(0);	/* failed to make vault - very strange */
287.  }
288.  
289.  addrs(lowx,lowy,hix,hiy)
290.  register int lowx,lowy,hix,hiy;
291.  {
292.  	register struct rectangle *rsp;
293.  	register int lx,ly,hx,hy,xlim,ylim;
294.  	boolean discarded;
295.  
296.  	xlim = XLIM + secret;
297.  	ylim = YLIM + secret;
298.  
299.  	/* walk down since rscnt and rsmax change */
300.  	for(rsp = &rs[rsmax-1]; rsp >= rs; rsp--) {
301.  		
302.  		if((lx = rsp->rlx) > hix || (ly = rsp->rly) > hiy ||
303.  		   (hx = rsp->rhx) < lowx || (hy = rsp->rhy) < lowy)
304.  			continue;
305.  		if((discarded = (rsp >= &rs[rscnt]))) {
306.  			*rsp = rs[--rsmax];
307.  		} else {
308.  			rsmax--;
309.  			rscnt--;
310.  			*rsp = rs[rscnt];
311.  			if(rscnt != rsmax)
312.  				rs[rscnt] = rs[rsmax];
313.  		}
314.  		if(lowy - ly > 2*ylim + 4)
315.  			addrsx(lx,ly,hx,lowy-2,discarded);
316.  		if(lowx - lx > 2*xlim + 4)
317.  			addrsx(lx,ly,lowx-2,hy,discarded);
318.  		if(hy - hiy > 2*ylim + 4)
319.  			addrsx(lx,hiy+2,hx,hy,discarded);
320.  		if(hx - hix > 2*xlim + 4)
321.  			addrsx(hix+2,ly,hx,hy,discarded);
322.  	}
323.  }
324.  
325.  addrsx(lx,ly,hx,hy,discarded)
326.  register int lx,ly,hx,hy;
327.  boolean discarded;		/* piece of a discarded area */
328.  {
329.  	register struct rectangle *rsp;
330.  
331.  	/* check inclusions */
332.  	for(rsp = rs; rsp < &rs[rsmax]; rsp++) {
333.  		if(lx >= rsp->rlx && hx <= rsp->rhx &&
334.  		   ly >= rsp->rly && hy <= rsp->rhy)
335.  			return;
336.  	}
337.  
338.  	/* make a new entry */
339.  	if(rsmax >= MAXRS) {
340.  #ifdef WIZARD
341.  		if(wizard) pline("MAXRS may be too small.");
342.  #endif
343.  		return;
344.  	}
345.  	rsmax++;
346.  	if(!discarded) {
347.  		*rsp = rs[rscnt];
348.  		rsp = &rs[rscnt];
349.  		rscnt++;
350.  	}
351.  	rsp->rlx = lx;
352.  	rsp->rly = ly;
353.  	rsp->rhx = hx;
354.  	rsp->rhy = hy;
355.  }
356.  
357.  comp(x,y)
358.  register struct mkroom *x,*y;
359.  {
360.  	if(x->lx < y->lx) return(-1);
361.  	return(x->lx > y->lx);
362.  }
363.  
364.  finddpos(cc, xl,yl,xh,yh)
365.  coord	*cc;
366.  int	xl,yl,xh,yh;
367.  {
368.  	register x,y;
369.  
370.  	x = (xl == xh) ? xl : (xl + rn2(xh-xl+1));
371.  	y = (yl == yh) ? yl : (yl + rn2(yh-yl+1));
372.  	if(okdoor(x, y))
373.  		goto gotit;
374.  
375.  	for(x = xl; x <= xh; x++) for(y = yl; y <= yh; y++)
376.  		if(okdoor(x, y))
377.  			goto gotit;
378.  
379.  	for(x = xl; x <= xh; x++) for(y = yl; y <= yh; y++)
380.  		if(levl[x][y].typ == DOOR || levl[x][y].typ == SDOOR)
381.  			goto gotit;
382.  	/* cannot find something reasonable -- strange */
383.  	x = xl;
384.  	y = yh;
385.  gotit:
386.  	cc->x = x;
387.  	cc->y = y;
388.  	return(0);
389.  }
390.  
391.  /* see whether it is allowable to create a door at [x,y] */
392.  okdoor(x,y)
393.  register x,y;
394.  {
395.  	if(levl[x-1][y].typ == DOOR || levl[x+1][y].typ == DOOR ||
396.  	   levl[x][y+1].typ == DOOR || levl[x][y-1].typ == DOOR ||
397.  	   levl[x-1][y].typ == SDOOR || levl[x+1][y].typ == SDOOR ||
398.  	   levl[x][y-1].typ == SDOOR || levl[x][y+1].typ == SDOOR ||
399.  	   (levl[x][y].typ != HWALL && levl[x][y].typ != VWALL) ||
400.  	   doorindex >= DOORMAX)
401.  		return(0);
402.  	return(1);
403.  }
404.  
405.  dodoor(x,y,aroom)
406.  register x,y;
407.  register struct mkroom *aroom;
408.  {
409.  	if(doorindex >= DOORMAX) {
410.  		impossible("DOORMAX exceeded?");
411.  		return;
412.  	}
413.  	if(!okdoor(x,y) && nxcor)
414.  		return;
415.  	dosdoor(x,y,aroom,rn2(8) ? DOOR : SDOOR);
416.  }
417.  
418.  dosdoor(x,y,aroom,type)
419.  register x,y;
420.  register struct mkroom *aroom;
421.  register type;
422.  {
423.  	register struct mkroom *broom;
424.  	register tmp;
425.  
426.  	if(!IS_WALL(levl[x][y].typ))	/* avoid SDOORs with DOOR_SYM as scrsym */
427.  		type = DOOR;
428.  	levl[x][y].typ = type;
429.  	if(type == DOOR)
430.  		levl[x][y].scrsym = DOOR_SYM;
431.  	aroom->doorct++;
432.  	broom = aroom+1;
433.  	if(broom->hx < 0) tmp = doorindex; else
434.  	for(tmp = doorindex; tmp > broom->fdoor; tmp--)
435.  		doors[tmp] = doors[tmp-1];
436.  	doorindex++;
437.  	doors[tmp].x = x;
438.  	doors[tmp].y = y;
439.  	for( ; broom->hx >= 0; broom++) broom->fdoor++;
440.  }
441.  
442.  /* Only called from makerooms() */
443.  maker(lowx,ddx,lowy,ddy)
444.  schar lowx,ddx,lowy,ddy;
445.  {
446.  	register struct mkroom *croom;
447.  	register x, y, hix = lowx+ddx, hiy = lowy+ddy;
448.  	register xlim = XLIM + secret, ylim = YLIM + secret;
449.  
450.  	if(nroom >= MAXNROFROOMS) return(0);
451.  	if(lowx < XLIM) lowx = XLIM;
452.  	if(lowy < YLIM) lowy = YLIM;
453.  	if(hix > COLNO-XLIM-1) hix = COLNO-XLIM-1;
454.  	if(hiy > ROWNO-YLIM-1) hiy = ROWNO-YLIM-1;
455.  chk:
456.  	if(hix <= lowx || hiy <= lowy) return(0);
457.  
458.  	/* check area around room (and make room smaller if necessary) */
459.  	for(x = lowx - xlim; x <= hix + xlim; x++) {
460.  		for(y = lowy - ylim; y <= hiy + ylim; y++) {
461.  			if(levl[x][y].typ) {
462.  #ifdef WIZARD
463.  			    if(wizard && !secret)
464.  				pline("Strange area [%d,%d] in maker().",x,y);
465.  #endif
466.  				if(!rn2(3)) return(0);
467.  				if(x < lowx)
468.  					lowx = x+xlim+1;
469.  				else
470.  					hix = x-xlim-1;
471.  				if(y < lowy)
472.  					lowy = y+ylim+1;
473.  				else
474.  					hiy = y-ylim-1;
475.  				goto chk;
476.  			}
477.  		}
478.  	}
479.  
480.  	croom = &rooms[nroom];
481.  
482.  	/* on low levels the room is lit (usually) */
483.  	/* secret vaults are always lit */
484.  	if((rnd(dlevel) < 10 && rn2(77)) || (ddx == 1 && ddy == 1)) {
485.  		for(x = lowx-1; x <= hix+1; x++)
486.  			for(y = lowy-1; y <= hiy+1; y++)
487.  				levl[x][y].lit = 1;
488.  		croom->rlit = 1;
489.  	} else
490.  		croom->rlit = 0;
491.  	croom->lx = lowx;
492.  	croom->hx = hix;
493.  	croom->ly = lowy;
494.  	croom->hy = hiy;
495.  	croom->rtype = OROOM;
496.  	croom->doorct = croom->fdoor = 0;
497.  
498.  	for(x = lowx-1; x <= hix+1; x++)
499.  	    for(y = lowy-1; y <= hiy+1; y += (hiy-lowy+2)) {
500.  		levl[x][y].scrsym = HWALL_SYM;
501.  		levl[x][y].typ = HWALL;
502.  	}
503.  	for(x = lowx-1; x <= hix+1; x += (hix-lowx+2))
504.  	    for(y = lowy; y <= hiy; y++) {
505.  		levl[x][y].scrsym = VWALL_SYM;
506.  		levl[x][y].typ = VWALL;
507.  	}
508.  	for(x = lowx; x <= hix; x++)
509.  	    for(y = lowy; y <= hiy; y++) {
510.  		levl[x][y].scrsym = ROOM_SYM;
511.  		levl[x][y].typ = ROOM;
512.  	}
513.  	levl[lowx-1][lowy-1].scrsym = TLCORN_SYM;
514.  	levl[hix+1][lowy-1].scrsym = TRCORN_SYM;
515.  	levl[lowx-1][hiy+1].scrsym = BLCORN_SYM;
516.  	levl[hix+1][hiy+1].scrsym = BRCORN_SYM;
517.  
518.  	smeq[nroom] = nroom;
519.  	croom++;
520.  	croom->hx = -1;
521.  	nroom++;
522.  	return(1);
523.  }
524.  
525.  makecorridors() {
526.  	register a,b;
527.  
528.  	nxcor = 0;
529.  	for(a = 0; a < nroom-1; a++)
530.  		join(a, a+1);
531.  	for(a = 0; a < nroom-2; a++)
532.  	    if(smeq[a] != smeq[a+2])
533.  		join(a, a+2);
534.  	for(a = 0; a < nroom; a++)
535.  	    for(b = 0; b < nroom; b++)
536.  		if(smeq[a] != smeq[b])
537.  		    join(a, b);
538.  	if(nroom > 2)
539.  	    for(nxcor = rn2(nroom) + 4; nxcor; nxcor--) {
540.  		a = rn2(nroom);
541.  		b = rn2(nroom-2);
542.  		if(b >= a) b += 2;
543.  		join(a, b);
544.  	    }
545.  }
546.  
547.  join(a,b)
548.  register a,b;
549.  {
550.  	coord cc,tt;
551.  	register tx, ty, xx, yy;
552.  	register struct rm *crm;
553.  	register struct mkroom *croom, *troom;
554.  	register dx, dy, dix, diy, cct;
555.  
556.  	croom = &rooms[a];
557.  	troom = &rooms[b];
558.  
559.  	/* find positions cc and tt for doors in croom and troom
560.  	   and direction for a corridor between them */
561.  
562.  	if(troom->hx < 0 || croom->hx < 0 || doorindex >= DOORMAX) return;
563.  	if(troom->lx > croom->hx) {
564.  		dx = 1;
565.  		dy = 0;
566.  		xx = croom->hx+1;
567.  		tx = troom->lx-1;
568.  		finddpos(&cc, xx, croom->ly, xx, croom->hy);
569.  		finddpos(&tt, tx, troom->ly, tx, troom->hy);
570.  	} else if(troom->hy < croom->ly) {
571.  		dy = -1;
572.  		dx = 0;
573.  		yy = croom->ly-1;
574.  		finddpos(&cc, croom->lx, yy, croom->hx, yy);
575.  		ty = troom->hy+1;
576.  		finddpos(&tt, troom->lx, ty, troom->hx, ty);
577.  	} else if(troom->hx < croom->lx) {
578.  		dx = -1;
579.  		dy = 0;
580.  		xx = croom->lx-1;
581.  		tx = troom->hx+1;
582.  		finddpos(&cc, xx, croom->ly, xx, croom->hy);
583.  		finddpos(&tt, tx, troom->ly, tx, troom->hy);
584.  	} else {
585.  		dy = 1;
586.  		dx = 0;
587.  		yy = croom->hy+1;
588.  		ty = troom->ly-1;
589.  		finddpos(&cc, croom->lx, yy, croom->hx, yy);
590.  		finddpos(&tt, troom->lx, ty, troom->hx, ty);
591.  	}
592.  	xx = cc.x;
593.  	yy = cc.y;
594.  	tx = tt.x - dx;
595.  	ty = tt.y - dy;
596.  	if(nxcor && levl[xx+dx][yy+dy].typ)
597.  		return;
598.  	dodoor(xx,yy,croom);
599.  
600.  	cct = 0;
601.  	while(xx != tx || yy != ty) {
602.  	    xx += dx;
603.  	    yy += dy;
604.  
605.  	    /* loop: dig corridor at [xx,yy] and find new [xx,yy] */
606.  	    if(cct++ > 500 || (nxcor && !rn2(35)))
607.  		return;
608.  
609.  	    if(xx == COLNO-1 || xx == 0 || yy == 0 || yy == ROWNO-1)
610.  		return;		/* impossible */
611.  
612.  	    crm = &levl[xx][yy];
613.  	    if(!(crm->typ)) {
614.  		if(rn2(100)) {
615.  			crm->typ = CORR;
616.  			crm->scrsym = CORR_SYM;
617.  			if(nxcor && !rn2(50))
618.  				(void) mkobj_at(ROCK_SYM, xx, yy);
619.  		} else {
620.  			crm->typ = SCORR;
621.  			crm->scrsym = STONE_SYM;
622.  		}
623.  	    } else
624.  	    if(crm->typ != CORR && crm->typ != SCORR) {
625.  		/* strange ... */
626.  		return;
627.  	    }
628.  
629.  	    /* find next corridor position */
630.  	    dix = abs(xx-tx);
631.  	    diy = abs(yy-ty);
632.  
633.  	    /* do we have to change direction ? */
634.  	    if(dy && dix > diy) {
635.  		register ddx = (xx > tx) ? -1 : 1;
636.  
637.  		crm = &levl[xx+ddx][yy];
638.  		if(!crm->typ || crm->typ == CORR || crm->typ == SCORR) {
639.  		    dx = ddx;
640.  		    dy = 0;
641.  		    continue;
642.  		}
643.  	    } else if(dx && diy > dix) {
644.  		register ddy = (yy > ty) ? -1 : 1;
645.  
646.  		crm = &levl[xx][yy+ddy];
647.  		if(!crm->typ || crm->typ == CORR || crm->typ == SCORR) {
648.  		    dy = ddy;
649.  		    dx = 0;
650.  		    continue;
651.  		}
652.  	    }
653.  
654.  	    /* continue straight on? */
655.  	    crm = &levl[xx+dx][yy+dy];
656.  	    if(!crm->typ || crm->typ == CORR || crm->typ == SCORR)
657.  		continue;
658.  
659.  	    /* no, what must we do now?? */
660.  	    if(dx) {
661.  		dx = 0;
662.  		dy = (ty < yy) ? -1 : 1;
663.  		crm = &levl[xx+dx][yy+dy];
664.  		if(!crm->typ || crm->typ == CORR || crm->typ == SCORR)
665.  		    continue;
666.  		dy = -dy;
667.  		continue;
668.  	    } else {
669.  		dy = 0;
670.  		dx = (tx < xx) ? -1 : 1;
671.  		crm = &levl[xx+dx][yy+dy];
672.  		if(!crm->typ || crm->typ == CORR || crm->typ == SCORR)
673.  		    continue;
674.  		dx = -dx;
675.  		continue;
676.  	    }
677.  	}
678.  
679.  	/* we succeeded in digging the corridor */
680.  	dodoor(tt.x, tt.y, troom);
681.  
682.  	if(smeq[a] < smeq[b])
683.  		smeq[b] = smeq[a];
684.  	else
685.  		smeq[a] = smeq[b];
686.  }
687.  
688.  make_niches()
689.  {
690.  	register int ct = rnd(nroom/2 + 1);
691.  #ifdef NEWCLASS
692.  	boolean	ltptr = TRUE,
693.  		vamp = TRUE;
694.  
695.  	while(ct--) {
696.  
697.  		if(dlevel > 15 && !rn2(6) && ltptr) {
698.  
699.  			ltptr = FALSE;
700.  			makeniche(LEVEL_TELEP);
701.  		} else if (dlevel > 5 && dlevel < 25
702.  			   && !rn2(6) && vamp) {
703.  
704.  			vamp = FALSE;
705.  			makeniche(TRAPDOOR);
706.  		} else	makeniche(NO_TRAP);
707.  	}
708.  #else
709.  	while(ct--) makeniche(NO_TRAP);
710.  #endif
711.  }
712.  
713.  makevtele()
714.  {
715.  	makeniche(TELEP_TRAP);
716.  }
717.  
718.  /* there should be one of these per trap */
719.  char    *engravings[] = {       "", "", "", "", "",
720.  				"ad ae?ar um", "?la? ?as ?er?",
721.  				"", "", ""
722.  #ifdef NEWTRAPS
723.  				,"", ""
724.  #endif
725.  #ifdef SPIDERS
726.  				,""
727.  #endif
728.  #ifdef NEWCLASS
729.  				, "", "ad ae?ar um"
730.  #endif
731.  #ifdef SPELLS
732.  				,""
733.  #endif
734.  #ifdef KAA
735.  				,""
736.  #ifdef RPH
737.  				,""
738.  #endif
739.  #endif
740.  #ifdef SAC
741.  				,""
742.  #endif
743.  				};
744.  
745.  makeniche(trap_type)
746.  int trap_type;
747.  {
748.  	register struct mkroom *aroom;
749.  	register struct rm *rm;
750.  	register int vct = 8;
751.  	coord dd;
752.  	register dy,xx,yy;
753.  	register struct trap *ttmp;
754.  
755.  	if(doorindex < DOORMAX)
756.  	  while(vct--) {
757.  	    aroom = &rooms[rn2(nroom-1)];
758.  	    if(aroom->rtype != OROOM) continue;	/* not an ordinary room */
759.  	    if(aroom->doorct == 1 && rn2(5)) continue;
760.  	    if(rn2(2)) {
761.  		dy = 1;
762.  		finddpos(&dd, aroom->lx, aroom->hy+1, aroom->hx, aroom->hy+1);
763.  	    } else {
764.  		dy = -1;
765.  		finddpos(&dd, aroom->lx, aroom->ly-1, aroom->hx, aroom->ly-1);
766.  	    }
767.  	    xx = dd.x;
768.  	    yy = dd.y;
769.  	    if((rm = &levl[xx][yy+dy])->typ) continue;
770.  	    if(trap_type || !rn2(4)) {
771.  
772.  		rm->typ = SCORR;
773.  		rm->scrsym = STONE_SYM;
774.  		if(trap_type) {
775.  		    ttmp = maketrap(xx, yy+dy, trap_type);
776.  		    ttmp->once = 1;
777.  		    if (strlen(engravings[trap_type]) > 0)
778.  			make_engr_at(xx, yy-dy, engravings[trap_type]);
779.  		}
780.  		dosdoor(xx, yy, aroom, SDOOR);
781.  	    } else {
782.  		rm->typ = CORR;
783.  		rm->scrsym = CORR_SYM;
784.  		if(rn2(7))
785.  		    dosdoor(xx, yy, aroom, rn2(5) ? SDOOR : DOOR);
786.  		else {
787.  		    mksobj_at(SCR_TELEPORTATION, xx, yy+dy);
788.  		    if(!rn2(3)) (void) mkobj_at(0, xx, yy+dy);
789.  		}
790.  	    }
791.  	    return;
792.  	}
793.  }
794.  
795.  /* make a trap somewhere (in croom if mazeflag = 0) */
796.  mktrap(num, mazeflag, croom)
797.  #ifndef REGBUG
798.  register
799.  #endif
800.  	 int num, mazeflag;
801.  #ifndef REGBUG
802.  register
803.  #endif
804.  	 struct mkroom *croom;
805.  {
806.  #ifndef REGBUG
807.  	register
808.  #endif
809.  		 struct trap *ttmp;
810.  #ifndef REGBUG
811.  	register
812.  #endif
813.  		int kind,nopierc,nomimic,fakedoor,fakegold,
814.  #ifdef SPIDERS
815.  		    nospider,
816.  #endif
817.  #ifdef NEWCLASS
818.  		    nospikes, nolevltp,
819.  #endif
820.  #ifdef SAC
821.  		    nolandmine,
822.  #endif
823.  		    tryct = 0;
824.  
825.  	xchar mx,my;
826.  	extern char fut_geno[];
827.  
828.  	if(!num || num >= TRAPNUM) {
829.  		nopierc = (dlevel < 4) ? 1 : 0;
830.  #ifdef NEWCLASS
831.  		nolevltp = (dlevel < 5) ? 1 : 0;
832.  		nospikes = (dlevel < 6) ? 1 : 0;
833.  #endif
834.  #ifdef SPIDERS
835.  		nospider = (dlevel < 7) ? 1 : 0;
836.  #endif
837.  #ifdef SAC
838.  		nolandmine = (dlevel < 5) ? 1 : 0;
839.  #endif
840.  		nomimic = (dlevel < 9 || goldseen ) ? 1 : 0;
841.  		if(index(fut_geno, 'M')) nomimic = 1;
842.  
843.  		do {
844.  		    kind = rnd(TRAPNUM-1);
845.  			if((kind == PIERC && nopierc) ||
846.  			   (kind == MIMIC && nomimic)
847.  #ifdef SPIDERS
848.  			   || ((kind == WEB) && nospider)
849.  #endif
850.  #ifdef NEWCLASS
851.  			   || (kind == SPIKED_PIT && nospikes)
852.  			   || (kind == LEVEL_TELEP && nolevltp)
853.  #endif
854.  #ifdef SAC
855.  			   || (kind == LANDMINE && nolandmine)
856.  #endif
857.  			   )  kind = NO_TRAP;
858.  		} while(kind == NO_TRAP);
859.  	} else kind = num;
860.  
861.  	if(kind == MIMIC) {
862.  		register struct monst *mtmp;
863.  
864.  		fakedoor = (!rn2(3) && !mazeflag);
865.  		fakegold = (!fakedoor && !rn2(2));
866.  		if(fakegold) goldseen = TRUE;
867.  		do {
868.  			if(++tryct > 200) return;
869.  			if(fakedoor) {
870.  				/* note: fakedoor maybe on actual door */
871.  				if(rn2(2)){
872.  				    if(rn2(2))	mx = croom->hx+1;
873.  				    else	mx = croom->lx-1;
874.  				    my = somey();
875.  				} else {
876.  				    if(rn2(2))	my = croom->hy+1;
877.  				    else	my = croom->ly-1;
878.  				    mx = somex();
879.  				}
880.  			} else if(mazeflag) {
881.  				coord mm;
882.  				mazexy(&mm);
883.  				mx = mm.x;
884.  				my = mm.y;
885.  			} else {
886.  				mx = somex();
887.  				my = somey();
888.  			}
889.  		} while(m_at(mx,my) || levl[mx][my].typ == STAIRS);
890.  		if(mtmp = makemon(PM_MIMIC,mx,my)) {
891.  		    mtmp->mimic = 1;
892.  		    mtmp->mappearance =
893.  			fakegold ? '$' : fakedoor ? DOOR_SYM :
894.  			(mazeflag && rn2(2)) ? AMULET_SYM :
895.  #ifdef SPELLS
896.  			"=/)%?![<>+" [ rn2(10) ];
897.  #else
898.  			"=/)%?![<>" [ rn2(9) ];
899.  #endif
900.  		}
901.  		return;
902.  	}
903.  
904.  	do {
905.  		if(++tryct > 200)
906.  			return;
907.  		if(mazeflag){
908.  			coord mm;
909.  			mazexy(&mm);
910.  			mx = mm.x;
911.  			my = mm.y;
912.  		} else {
913.  			mx = somex();
914.  			my = somey();
915.  		}
916.  	} while(t_at(mx, my) || levl[mx][my].typ == STAIRS);
917.  	ttmp = maketrap(mx, my, kind);
918.  #ifdef SPIDERS
919.  	if (kind == WEB) mkmon_at ('s', mx, my);
920.  #endif
921.  	if(mazeflag && !rn2(10) && ttmp->ttyp < PIERC)
922.  		ttmp->tseen = 1;
923.  }
924.  
925.  #ifdef FOUNTAINS
926.  mkfount(mazeflag,croom)
927.  register struct mkroom *croom;
928.  register mazeflag;
929.  {
930.        register xchar mx,my;
931.        register int tryct = 0;
932.  
933.        do {
934.  	      if(++tryct > 200)
935.  		      return;
936.  	      if(mazeflag){
937.  		      coord mm;
938.  		      mazexy(&mm);
939.  		      mx = mm.x;
940.  		      my = mm.y;
941.  	      } else {
942.  		      mx = somex();
943.  		      my = somey();
944.  	      }
945.        } while(t_at(mx, my) || levl[mx][my].typ == STAIRS
946.  #ifdef NEWCLASS
947.  	      || IS_THRONE(levl[mx][my].typ)
948.  #endif
949.  	     );
950.  
951.         /* Put a fountain at mx, my */
952.  
953.         levl[mx][my].typ = FOUNTAIN;
954.         levl[mx][my].scrsym = FOUNTAIN_SYM;
955.  
956.  }
957.  #endif /* FOUNTAINS /**/
958.  
959.  #ifdef SINKS
960.  mksink(croom)
961.  register struct mkroom *croom;
962.  {
963.        register xchar mx,my;
964.        register int tryct = 0;
965.  
966.        do {
967.  	      if(++tryct > 200)
968.  		      return;
969.  	      mx = somex();
970.  	      my = somey();
971.        } while(t_at(mx, my) || levl[mx][my].typ == STAIRS
972.  #ifdef FOUNTAINS
973.  	      || IS_FOUNTAIN(levl[mx][my].typ)
974.  #endif
975.  #ifdef NEWCLASS
976.  	      || IS_THRONE(levl[mx][my].typ)
977.  #endif
978.  	     );
979.  
980.         /* Put a sink at mx, my */
981.  
982.         levl[mx][my].typ = SINK;
983.         levl[mx][my].scrsym = SINK_SYM;
984.  
985.  }
986.  #endif /* SINKS /**/

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