freebsd-nq/games/rogue/level.c
Steve Price af71cfbb87 Merge a bunch of cleanups from NetBSD.
PR:		8083
Submitted by:	Stephen J. Roznowski <sjr@home.net>
Obtained from:	a whole slew of NetBSD PRs
1999-04-19 03:59:02 +00:00

882 lines
19 KiB
C

/*
* Copyright (c) 1988, 1993
* The Regents of the University of California. All rights reserved.
*
* This code is derived from software contributed to Berkeley by
* Timothy C. Stoehr.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* 3. All advertising materials mentioning features or use of this software
* must display the following acknowledgement:
* This product includes software developed by the University of
* California, Berkeley and its contributors.
* 4. Neither the name of the University nor the names of its contributors
* may be used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*/
#ifndef lint
static char sccsid[] = "@(#)level.c 8.1 (Berkeley) 5/31/93";
#endif /* not lint */
/*
* level.c
*
* This source herein may be modified and/or distributed by anybody who
* so desires, with the following restrictions:
* 1.) No portion of this notice shall be removed.
* 2.) Credit shall not be taken for the creation of this source.
* 3.) This code is not to be traded, sold, or used for personal
* gain or profit.
*
*/
#include "rogue.h"
#define swap(x,y) {t = x; x = y; y = t;}
short cur_level = 0;
short max_level = 1;
short cur_room;
const char *new_level_message = 0;
short party_room = NO_ROOM;
short r_de;
const long level_points[MAX_EXP_LEVEL] = {
10L,
20L,
40L,
80L,
160L,
320L,
640L,
1300L,
2600L,
5200L,
10000L,
20000L,
40000L,
80000L,
160000L,
320000L,
1000000L,
3333333L,
6666666L,
MAX_EXP,
99900000L
};
short random_rooms[MAXROOMS] = {3, 7, 5, 2, 0, 6, 1, 4, 8};
extern boolean being_held, wizard, detect_monster;
extern boolean see_invisible;
extern short bear_trap, levitate, extra_hp, less_hp, cur_room;
make_level()
{
short i, j;
short must_1, must_2, must_3;
boolean big_room;
if (cur_level < LAST_DUNGEON) {
cur_level++;
}
if (cur_level > max_level) {
max_level = cur_level;
}
must_1 = get_rand(0, 5);
switch(must_1) {
case 0:
must_1 = 0;
must_2 = 1;
must_3 = 2;
break;
case 1:
must_1 = 3;
must_2 = 4;
must_3 = 5;
break;
case 2:
must_1 = 6;
must_2 = 7;
must_3 = 8;
break;
case 3:
must_1 = 0;
must_2 = 3;
must_3 = 6;
break;
case 4:
must_1 = 1;
must_2 = 4;
must_3 = 7;
break;
case 5:
must_1 = 2;
must_2 = 5;
must_3 = 8;
break;
}
if (rand_percent(8)) {
party_room = 0;
}
big_room = ((party_room != NO_ROOM) && rand_percent(1));
if (big_room) {
make_room(BIG_ROOM, 0, 0, 0);
} else {
for (i = 0; i < MAXROOMS; i++) {
make_room(i, must_1, must_2, must_3);
}
}
if (!big_room) {
add_mazes();
mix_random_rooms();
for (j = 0; j < MAXROOMS; j++) {
i = random_rooms[j];
if (i < (MAXROOMS-1)) {
(void) connect_rooms(i, i+1);
}
if (i < (MAXROOMS-3)) {
(void) connect_rooms(i, i+3);
}
if (i < (MAXROOMS-2)) {
if (rooms[i+1].is_room & R_NOTHING) {
if (connect_rooms(i, i+2)) {
rooms[i+1].is_room = R_CROSS;
}
}
}
if (i < (MAXROOMS-6)) {
if (rooms[i+3].is_room & R_NOTHING) {
if (connect_rooms(i, i+6)) {
rooms[i+3].is_room = R_CROSS;
}
}
}
if (is_all_connected()) {
break;
}
}
fill_out_level();
}
if (!has_amulet() && (cur_level >= AMULET_LEVEL)) {
put_amulet();
}
}
make_room(rn, r1, r2, r3)
short rn, r1, r2, r3;
{
short left_col, right_col, top_row, bottom_row;
short width, height;
short row_offset, col_offset;
short i, j, ch;
switch(rn) {
case 0:
left_col = 0;
right_col = COL1-1;
top_row = MIN_ROW;
bottom_row = ROW1-1;
break;
case 1:
left_col = COL1+1;
right_col = COL2-1;
top_row = MIN_ROW;
bottom_row = ROW1-1;
break;
case 2:
left_col = COL2+1;
right_col = DCOLS-1;
top_row = MIN_ROW;
bottom_row = ROW1-1;
break;
case 3:
left_col = 0;
right_col = COL1-1;
top_row = ROW1+1;
bottom_row = ROW2-1;
break;
case 4:
left_col = COL1+1;
right_col = COL2-1;
top_row = ROW1+1;
bottom_row = ROW2-1;
break;
case 5:
left_col = COL2+1;
right_col = DCOLS-1;
top_row = ROW1+1;
bottom_row = ROW2-1;
break;
case 6:
left_col = 0;
right_col = COL1-1;
top_row = ROW2+1;
bottom_row = DROWS - 2;
break;
case 7:
left_col = COL1+1;
right_col = COL2-1;
top_row = ROW2+1;
bottom_row = DROWS - 2;
break;
case 8:
left_col = COL2+1;
right_col = DCOLS-1;
top_row = ROW2+1;
bottom_row = DROWS - 2;
break;
case BIG_ROOM:
top_row = get_rand(MIN_ROW, MIN_ROW+5);
bottom_row = get_rand(DROWS-7, DROWS-2);
left_col = get_rand(0, 10);;
right_col = get_rand(DCOLS-11, DCOLS-1);
rn = 0;
goto B;
}
height = get_rand(4, (bottom_row - top_row + 1));
width = get_rand(7, (right_col - left_col - 2));
row_offset = get_rand(0, ((bottom_row - top_row) - height + 1));
col_offset = get_rand(0, ((right_col - left_col) - width + 1));
top_row += row_offset;
bottom_row = top_row + height - 1;
left_col += col_offset;
right_col = left_col + width - 1;
if ((rn != r1) && (rn != r2) && (rn != r3) && rand_percent(40)) {
goto END;
}
B:
rooms[rn].is_room = R_ROOM;
for (i = top_row; i <= bottom_row; i++) {
for (j = left_col; j <= right_col; j++) {
if ((i == top_row) || (i == bottom_row)) {
ch = HORWALL;
} else if ( ((i != top_row) && (i != bottom_row)) &&
((j == left_col) || (j == right_col))) {
ch = VERTWALL;
} else {
ch = FLOOR;
}
dungeon[i][j] = ch;
}
}
END:
rooms[rn].top_row = top_row;
rooms[rn].bottom_row = bottom_row;
rooms[rn].left_col = left_col;
rooms[rn].right_col = right_col;
}
connect_rooms(room1, room2)
short room1, room2;
{
short row1, col1, row2, col2, dir;
if ((!(rooms[room1].is_room & (R_ROOM | R_MAZE))) ||
(!(rooms[room2].is_room & (R_ROOM | R_MAZE)))) {
return(0);
}
if (same_row(room1, room2) &&
(rooms[room1].left_col > rooms[room2].right_col)) {
put_door(&rooms[room1], LEFT, &row1, &col1);
put_door(&rooms[room2], RIGHT, &row2, &col2);
dir = LEFT;
} else if (same_row(room1, room2) &&
(rooms[room2].left_col > rooms[room1].right_col)) {
put_door(&rooms[room1], RIGHT, &row1, &col1);
put_door(&rooms[room2], LEFT, &row2, &col2);
dir = RIGHT;
} else if (same_col(room1, room2) &&
(rooms[room1].top_row > rooms[room2].bottom_row)) {
put_door(&rooms[room1], UPWARD, &row1, &col1);
put_door(&rooms[room2], DOWN, &row2, &col2);
dir = UPWARD;
} else if (same_col(room1, room2) &&
(rooms[room2].top_row > rooms[room1].bottom_row)) {
put_door(&rooms[room1], DOWN, &row1, &col1);
put_door(&rooms[room2], UPWARD, &row2, &col2);
dir = DOWN;
} else {
return(0);
}
do {
draw_simple_passage(row1, col1, row2, col2, dir);
} while (rand_percent(4));
rooms[room1].doors[dir/2].oth_room = room2;
rooms[room1].doors[dir/2].oth_row = row2;
rooms[room1].doors[dir/2].oth_col = col2;
rooms[room2].doors[(((dir+4)%DIRS)/2)].oth_room = room1;
rooms[room2].doors[(((dir+4)%DIRS)/2)].oth_row = row1;
rooms[room2].doors[(((dir+4)%DIRS)/2)].oth_col = col1;
return(1);
}
clear_level()
{
short i, j;
for (i = 0; i < MAXROOMS; i++) {
rooms[i].is_room = R_NOTHING;
for (j = 0; j < 4; j++) {
rooms[i].doors[j].oth_room = NO_ROOM;
}
}
for (i = 0; i < MAX_TRAPS; i++) {
traps[i].trap_type = NO_TRAP;
}
for (i = 0; i < DROWS; i++) {
for (j = 0; j < DCOLS; j++) {
dungeon[i][j] = NOTHING;
}
}
detect_monster = see_invisible = 0;
being_held = bear_trap = 0;
party_room = NO_ROOM;
rogue.row = rogue.col = -1;
clear();
}
put_door(rm, dir, row, col)
room *rm;
short dir;
short *row, *col;
{
short wall_width;
wall_width = (rm->is_room & R_MAZE) ? 0 : 1;
switch(dir) {
case UPWARD:
case DOWN:
*row = ((dir == UPWARD) ? rm->top_row : rm->bottom_row);
do {
*col = get_rand(rm->left_col+wall_width,
rm->right_col-wall_width);
} while (!(dungeon[*row][*col] & (HORWALL | TUNNEL)));
break;
case RIGHT:
case LEFT:
*col = (dir == LEFT) ? rm->left_col : rm->right_col;
do {
*row = get_rand(rm->top_row+wall_width,
rm->bottom_row-wall_width);
} while (!(dungeon[*row][*col] & (VERTWALL | TUNNEL)));
break;
}
if (rm->is_room & R_ROOM) {
dungeon[*row][*col] = DOOR;
}
if ((cur_level > 2) && rand_percent(HIDE_PERCENT)) {
dungeon[*row][*col] |= HIDDEN;
}
rm->doors[dir/2].door_row = *row;
rm->doors[dir/2].door_col = *col;
}
draw_simple_passage(row1, col1, row2, col2, dir)
short row1, col1, row2, col2, dir;
{
short i, middle, t;
if ((dir == LEFT) || (dir == RIGHT)) {
if (col1 > col2) {
swap(row1, row2);
swap(col1, col2);
}
middle = get_rand(col1+1, col2-1);
for (i = col1+1; i != middle; i++) {
dungeon[row1][i] = TUNNEL;
}
for (i = row1; i != row2; i += (row1 > row2) ? -1 : 1) {
dungeon[i][middle] = TUNNEL;
}
for (i = middle; i != col2; i++) {
dungeon[row2][i] = TUNNEL;
}
} else {
if (row1 > row2) {
swap(row1, row2);
swap(col1, col2);
}
middle = get_rand(row1+1, row2-1);
for (i = row1+1; i != middle; i++) {
dungeon[i][col1] = TUNNEL;
}
for (i = col1; i != col2; i += (col1 > col2) ? -1 : 1) {
dungeon[middle][i] = TUNNEL;
}
for (i = middle; i != row2; i++) {
dungeon[i][col2] = TUNNEL;
}
}
if (rand_percent(HIDE_PERCENT)) {
hide_boxed_passage(row1, col1, row2, col2, 1);
}
}
same_row(room1, room2)
{
return((room1 / 3) == (room2 / 3));
}
same_col(room1, room2)
{
return((room1 % 3) == (room2 % 3));
}
add_mazes()
{
short i, j;
short start;
short maze_percent;
if (cur_level > 1) {
start = get_rand(0, (MAXROOMS-1));
maze_percent = (cur_level * 5) / 4;
if (cur_level > 15) {
maze_percent += cur_level;
}
for (i = 0; i < MAXROOMS; i++) {
j = ((start + i) % MAXROOMS);
if (rooms[j].is_room & R_NOTHING) {
if (rand_percent(maze_percent)) {
rooms[j].is_room = R_MAZE;
make_maze(get_rand(rooms[j].top_row+1, rooms[j].bottom_row-1),
get_rand(rooms[j].left_col+1, rooms[j].right_col-1),
rooms[j].top_row, rooms[j].bottom_row,
rooms[j].left_col, rooms[j].right_col);
hide_boxed_passage(rooms[j].top_row, rooms[j].left_col,
rooms[j].bottom_row, rooms[j].right_col,
get_rand(0, 2));
}
}
}
}
}
fill_out_level()
{
short i, rn;
mix_random_rooms();
r_de = NO_ROOM;
for (i = 0; i < MAXROOMS; i++) {
rn = random_rooms[i];
if ((rooms[rn].is_room & R_NOTHING) ||
((rooms[rn].is_room & R_CROSS) && coin_toss())) {
fill_it(rn, 1);
}
}
if (r_de != NO_ROOM) {
fill_it(r_de, 0);
}
}
fill_it(rn, do_rec_de)
int rn;
boolean do_rec_de;
{
short i, tunnel_dir, door_dir, drow, dcol;
short target_room, rooms_found = 0;
short srow, scol, t;
static short offsets[4] = {-1, 1, 3, -3};
boolean did_this = 0;
for (i = 0; i < 10; i++) {
srow = get_rand(0, 3);
scol = get_rand(0, 3);
t = offsets[srow];
offsets[srow] = offsets[scol];
offsets[scol] = t;
}
for (i = 0; i < 4; i++) {
target_room = rn + offsets[i];
if (((target_room < 0) || (target_room >= MAXROOMS)) ||
(!(same_row(rn,target_room) || same_col(rn,target_room))) ||
(!(rooms[target_room].is_room & (R_ROOM | R_MAZE)))) {
continue;
}
if (same_row(rn, target_room)) {
tunnel_dir = (rooms[rn].left_col < rooms[target_room].left_col) ?
RIGHT : LEFT;
} else {
tunnel_dir = (rooms[rn].top_row < rooms[target_room].top_row) ?
DOWN : UPWARD;
}
door_dir = ((tunnel_dir + 4) % DIRS);
if (rooms[target_room].doors[door_dir/2].oth_room != NO_ROOM) {
continue;
}
if (((!do_rec_de) || did_this) ||
(!mask_room(rn, &srow, &scol, TUNNEL))) {
srow = (rooms[rn].top_row + rooms[rn].bottom_row) / 2;
scol = (rooms[rn].left_col + rooms[rn].right_col) / 2;
}
put_door(&rooms[target_room], door_dir, &drow, &dcol);
rooms_found++;
draw_simple_passage(srow, scol, drow, dcol, tunnel_dir);
rooms[rn].is_room = R_DEADEND;
dungeon[srow][scol] = TUNNEL;
if ((i < 3) && (!did_this)) {
did_this = 1;
if (coin_toss()) {
continue;
}
}
if ((rooms_found < 2) && do_rec_de) {
recursive_deadend(rn, offsets, srow, scol);
}
break;
}
}
recursive_deadend(rn, offsets, srow, scol)
short rn;
const short *offsets;
short srow, scol;
{
short i, de;
short drow, dcol, tunnel_dir;
rooms[rn].is_room = R_DEADEND;
dungeon[srow][scol] = TUNNEL;
for (i = 0; i < 4; i++) {
de = rn + offsets[i];
if (((de < 0) || (de >= MAXROOMS)) ||
(!(same_row(rn, de) || same_col(rn, de)))) {
continue;
}
if (!(rooms[de].is_room & R_NOTHING)) {
continue;
}
drow = (rooms[de].top_row + rooms[de].bottom_row) / 2;
dcol = (rooms[de].left_col + rooms[de].right_col) / 2;
if (same_row(rn, de)) {
tunnel_dir = (rooms[rn].left_col < rooms[de].left_col) ?
RIGHT : LEFT;
} else {
tunnel_dir = (rooms[rn].top_row < rooms[de].top_row) ?
DOWN : UPWARD;
}
draw_simple_passage(srow, scol, drow, dcol, tunnel_dir);
r_de = de;
recursive_deadend(de, offsets, drow, dcol);
}
}
boolean
mask_room(rn, row, col, mask)
short rn;
short *row, *col;
unsigned short mask;
{
short i, j;
for (i = rooms[rn].top_row; i <= rooms[rn].bottom_row; i++) {
for (j = rooms[rn].left_col; j <= rooms[rn].right_col; j++) {
if (dungeon[i][j] & mask) {
*row = i;
*col = j;
return(1);
}
}
}
return(0);
}
make_maze(r, c, tr, br, lc, rc)
short r, c, tr, br, lc, rc;
{
char dirs[4];
short i, t;
dirs[0] = UPWARD;
dirs[1] = DOWN;
dirs[2] = LEFT;
dirs[3] = RIGHT;
dungeon[r][c] = TUNNEL;
if (rand_percent(20)) {
for (i = 0; i < 10; i++) {
short t1, t2;
t1 = get_rand(0, 3);
t2 = get_rand(0, 3);
swap(dirs[t1], dirs[t2]);
}
}
for (i = 0; i < 4; i++) {
switch(dirs[i]) {
case UPWARD:
if (((r-1) >= tr) &&
(dungeon[r-1][c] != TUNNEL) &&
(dungeon[r-1][c-1] != TUNNEL) &&
(dungeon[r-1][c+1] != TUNNEL) &&
(dungeon[r-2][c] != TUNNEL)) {
make_maze((r-1), c, tr, br, lc, rc);
}
break;
case DOWN:
if (((r+1) <= br) &&
(dungeon[r+1][c] != TUNNEL) &&
(dungeon[r+1][c-1] != TUNNEL) &&
(dungeon[r+1][c+1] != TUNNEL) &&
(dungeon[r+2][c] != TUNNEL)) {
make_maze((r+1), c, tr, br, lc, rc);
}
break;
case LEFT:
if (((c-1) >= lc) &&
(dungeon[r][c-1] != TUNNEL) &&
(dungeon[r-1][c-1] != TUNNEL) &&
(dungeon[r+1][c-1] != TUNNEL) &&
(dungeon[r][c-2] != TUNNEL)) {
make_maze(r, (c-1), tr, br, lc, rc);
}
break;
case RIGHT:
if (((c+1) <= rc) &&
(dungeon[r][c+1] != TUNNEL) &&
(dungeon[r-1][c+1] != TUNNEL) &&
(dungeon[r+1][c+1] != TUNNEL) &&
(dungeon[r][c+2] != TUNNEL)) {
make_maze(r, (c+1), tr, br, lc, rc);
}
break;
}
}
}
hide_boxed_passage(row1, col1, row2, col2, n)
short row1, col1, row2, col2, n;
{
short i, j, t;
short row, col, row_cut, col_cut;
short h, w;
if (cur_level > 2) {
if (row1 > row2) {
swap(row1, row2);
}
if (col1 > col2) {
swap(col1, col2);
}
h = row2 - row1;
w = col2 - col1;
if ((w >= 5) || (h >= 5)) {
row_cut = ((h >= 2) ? 1 : 0);
col_cut = ((w >= 2) ? 1 : 0);
for (i = 0; i < n; i++) {
for (j = 0; j < 10; j++) {
row = get_rand(row1 + row_cut, row2 - row_cut);
col = get_rand(col1 + col_cut, col2 - col_cut);
if (dungeon[row][col] == TUNNEL) {
dungeon[row][col] |= HIDDEN;
break;
}
}
}
}
}
}
put_player(nr)
short nr; /* try not to put in this room */
{
short rn = nr, misses;
short row, col;
for (misses = 0; ((misses < 2) && (rn == nr)); misses++) {
gr_row_col(&row, &col, (FLOOR | TUNNEL | OBJECT | STAIRS));
rn = get_room_number(row, col);
}
rogue.row = row;
rogue.col = col;
if (dungeon[rogue.row][rogue.col] & TUNNEL) {
cur_room = PASSAGE;
} else {
cur_room = rn;
}
if (cur_room != PASSAGE) {
light_up_room(cur_room);
} else {
light_passage(rogue.row, rogue.col);
}
rn = get_room_number(rogue.row, rogue.col);
wake_room(rn, 1, rogue.row, rogue.col);
if (new_level_message) {
message(new_level_message, 0);
new_level_message = 0;
}
mvaddch(rogue.row, rogue.col, rogue.fchar);
}
drop_check()
{
if (wizard) {
return(1);
}
if (dungeon[rogue.row][rogue.col] & STAIRS) {
if (levitate) {
message("you're floating in the air!", 0);
return(0);
}
return(1);
}
message("I see no way down", 0);
return(0);
}
check_up()
{
if (!wizard) {
if (!(dungeon[rogue.row][rogue.col] & STAIRS)) {
message("I see no way up", 0);
return(0);
}
if (!has_amulet()) {
message("your way is magically blocked", 0);
return(0);
}
}
new_level_message = "you feel a wrenching sensation in your gut";
if (cur_level == 1) {
win();
} else {
cur_level -= 2;
return(1);
}
return(0);
}
add_exp(e, promotion)
int e;
boolean promotion;
{
char mbuf[40];
short new_exp;
short i, hp;
rogue.exp_points += e;
if (rogue.exp_points >= level_points[rogue.exp-1]) {
new_exp = get_exp_level(rogue.exp_points);
if (rogue.exp_points > MAX_EXP) {
rogue.exp_points = MAX_EXP + 1;
}
for (i = rogue.exp+1; i <= new_exp; i++) {
sprintf(mbuf, "welcome to level %d", i);
message(mbuf, 0);
if (promotion) {
hp = hp_raise();
rogue.hp_current += hp;
rogue.hp_max += hp;
}
rogue.exp = i;
print_stats(STAT_HP | STAT_EXP);
}
} else {
print_stats(STAT_EXP);
}
}
get_exp_level(e)
long e;
{
short i;
for (i = 0; i < (MAX_EXP_LEVEL - 1); i++) {
if (level_points[i] > e) {
break;
}
}
return(i+1);
}
hp_raise()
{
int hp;
hp = (wizard ? 10 : get_rand(3, 10));
return(hp);
}
show_average_hp()
{
char mbuf[80];
float real_average;
float effective_average;
if (rogue.exp == 1) {
real_average = effective_average = 0.00;
} else {
real_average = (float)
((rogue.hp_max - extra_hp - INIT_HP) + less_hp) / (rogue.exp - 1);
effective_average = (float) (rogue.hp_max - INIT_HP) / (rogue.exp - 1);
}
sprintf(mbuf, "R-Hp: %.2f, E-Hp: %.2f (!: %d, V: %d)", real_average,
effective_average, extra_hp, less_hp);
message(mbuf, 0);
}
mix_random_rooms()
{
short i, t;
short x, y;
for (i = 0; i < (3 * MAXROOMS); i++) {
do {
x = get_rand(0, (MAXROOMS-1));
y = get_rand(0, (MAXROOMS-1));
} while (x == y);
swap(random_rooms[x], random_rooms[y]);
}
}