Mercurial > hg > early-roguelike
view urogue/maze.c @ 310:827441d05b3e
Advanced Rogue family: fix some potential buffer overflows.
Some code for determining the score file location assumed that PATH_MAX
would be less than 1024, which cannot be guaranteed.
Advanced Rogue 5 and 7, and XRogue, have had the buffers for the file
name enlarged. UltraRogue never called the functions, so the code has
been deleted instead.
author | John "Elwin" Edwards |
---|---|
date | Mon, 03 May 2021 19:05:37 -0400 |
parents | c495a4f288c6 |
children |
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/* maze.c - functions for dealing with armor UltraRogue: The Ultimate Adventure in the Dungeons of Doom Copyright (C) 1985, 1986, 1992, 1993, 1995 Herb Chong All rights reserved. Based on "Advanced Rogue" Copyright (C) 1984, 1985 Michael Morgan, Ken Dalka All rights reserved. See the file LICENSE.TXT for full copyright and licensing information. */ #include <stdlib.h> #include "rogue.h" static char *frontier; static char *bits; static int urlines; static int urcols; /* domaze() Draw the maze on this level. */ void do_maze(void) { int i, least; struct room *rp; struct linked_list *item; struct object *obj; struct thing *mp; int treas; coord tp; for (rp = rooms; rp < &rooms[MAXROOMS]; rp++) { rp->r_nexits = 0; /* no exits */ rp->r_flags = ISGONE; /* kill all rooms */ rp->r_fires = 0; /* no fires */ } rp = &rooms[0]; /* point to only room */ rp->r_flags = ISDARK; /* mazes always dark */ rp->r_pos.x = 0; /* room fills whole screen */ rp->r_pos.y = 1; rp->r_max.x = COLS - 1; rp->r_max.y = LINES - 3; draw_maze(); /* put maze into window */ /* add some gold to make it worth looking for */ item = spec_item(GOLD, 0, 0, 0); obj = OBJPTR(item); obj->o_count *= (rnd(10) + 5); /* add in one large hunk */ do { rnd_pos(rp, &tp); } while( mvwinch(stdscr, tp.y, tp.x) != FLOOR); obj->o_pos = tp; add_obj(item, tp.y, tp.x); /* add in some food to make sure he has enough */ item = spec_item(FOOD, 0, 0, 0); obj = OBJPTR(item); do { rnd_pos(rp, &tp); } while( mvwinch(stdscr, tp.y, tp.x) != FLOOR); obj->o_pos = tp; add_obj(item, tp.y, tp.x); if (rnd(100) < 5) /* 5% for treasure maze level */ { treas = TRUE; least = 20; debug("Treasure maze."); } else /* normal maze level */ { least = 1; treas = FALSE; } for (i = 0; i < level + least; i++) { if (!treas && rnd(100) < 50) /* put in some little buggers */ continue; /* Put the monster in */ item = new_item(sizeof *mp); mp = THINGPTR(item); do { rnd_pos(rp, &tp); } while(mvwinch(stdscr, tp.y, tp.x) != FLOOR); new_monster(item, randmonster(NOWANDER, NOGRAB), &tp, NOMAXSTATS); /* See if we want to give it a treasure to carry around. */ if (rnd(100) < monsters[mp->t_index].m_carry) attach(mp->t_pack, new_thing()); /* If it carries gold, give it some */ if (on(*mp, CARRYGOLD)) { item = spec_item(GOLD, 0, 0, 0); obj = OBJPTR(item); obj->o_count = GOLDCALC + GOLDCALC + GOLDCALC; obj->o_pos = mp->t_pos; attach(mp->t_pack, item); } } } /* draw_maze() Generate and draw the maze on the screen */ void draw_maze(void) { int i, j, more; char *ptr; urlines = (LINES - 3) / 2; urcols = (COLS - 1) / 2; bits = ur_alloc((unsigned int) ((LINES - 3) * (COLS - 1))); frontier = ur_alloc((unsigned int) (urlines * urcols)); ptr = frontier; while (ptr < (frontier + (urlines * urcols))) *ptr++ = TRUE; for (i = 0; i < LINES - 3; i++) { for (j = 0; j < COLS - 1; j++) { if (i % 2 == 1 && j % 2 == 1) *moffset(i, j) = FALSE; /* floor */ else *moffset(i, j) = TRUE; /* wall */ } } for (i = 0; i < urlines; i++) { for (j = 0; j < urcols; j++) { do more = findcells(i, j); while (more != 0); } } crankout(); ur_free(frontier); ur_free(bits); } /* moffset() Calculate memory address for bits */ char * moffset(int y, int x) { return (bits + (y * (COLS - 1)) + x); } /* foffset() Calculate memory address for frontier */ char * foffset(int y, int x) { return (frontier + (y * urcols) + x); } /* findcells() Figure out cells to open up */ int findcells(int y, int x) { int rtpos, i; struct { int num_pos; /* number of frontier cells next to you */ struct { int y_pos; int x_pos; } conn[4]; /* the y,x position of above cell */ } mborder; *foffset(y, x) = FALSE; mborder.num_pos = 0; if (y < urlines - 1) { /* look below */ if (*foffset(y + 1, x)) { mborder.conn[mborder.num_pos].y_pos = y + 1; mborder.conn[mborder.num_pos].x_pos = x; mborder.num_pos += 1; } } if (y > 0) /* look above */ { if (*foffset(y - 1, x)) { mborder.conn[mborder.num_pos].y_pos = y - 1; mborder.conn[mborder.num_pos].x_pos = x; mborder.num_pos += 1; } } if (x < urcols - 1) /* look right */ { if (*foffset(y, x + 1)) { mborder.conn[mborder.num_pos].y_pos = y; mborder.conn[mborder.num_pos].x_pos = x + 1; mborder.num_pos += 1; } } if (x > 0) /* look left */ { if (*foffset(y, x - 1)) { mborder.conn[mborder.num_pos].y_pos = y; mborder.conn[mborder.num_pos].x_pos = x - 1; mborder.num_pos += 1; } } if (mborder.num_pos == 0)/* no neighbors available */ return(0); else { i = rnd(mborder.num_pos); rtpos = mborder.num_pos - 1; rmwall(mborder.conn[i].y_pos, mborder.conn[i].x_pos, y, x); return(rtpos); } } /* rmwall() Removes appropriate walls from the maze */ void rmwall(int newy, int newx, int oldy, int oldx) { int xdif, ydif; xdif = newx - oldx; ydif = newy - oldy; *moffset((oldy * 2) + ydif + 1, (oldx * 2) + xdif + 1) = FALSE; findcells(newy, newx); } /* crankout() Does actual drawing of maze to window */ void crankout(void) { int x, y; for (y = 0; y < LINES - 3; y++) { move(y + 1, 0); for (x = 0; x < COLS - 1; x++) { if (*moffset(y, x)) /* here is a wall */ { if (y == 0 || y == LINES - 4) /* top or bottom line */ addch('-'); else if (x == 0 || x == COLS - 2) /* left | right side */ addch('|'); else if (y % 2 == 0 && x % 2 == 0) { if (*moffset(y, x - 1) || *moffset(y, x + 1)) addch('-'); else addch('|'); } else if (y % 2 == 0) addch('-'); else addch('|'); } else addch(FLOOR); } } }