Mercurial > hg > early-roguelike
view arogue5/maze.c @ 227:696277507a2e
Rogue V4, V5: disable a cheat granting permanent monster detection.
In these two games, a potion of monster detection turns on the player's
SEEMONST flag. A fuse is set to call turn_see() to turn the flag back
off. But the save and restore functions do not recognize turn_see() and
fail to set the fuse up again.
When restoring, Rogue V4 merely sets the fuse's function to NULL and
leaves it burning. When it goes off, a segfault results. Rogue V5
clears all the fuse's fields, and the player retains the ability to see
all monsters on the level.
The save and restore code can now handle the fuse. The function used is
a new wrapper, turn_see_off(), which should lead to less problems with
daemons being multiple incompatible types.
Also, Rogue V4 and Super-Rogue now properly clear unrecognized daemon
and fuse slots when restoring a saved game.
| author | John "Elwin" Edwards |
|---|---|
| date | Sat, 05 Mar 2016 12:10:20 -0500 |
| parents | 56e748983fa8 |
| children | 0250220d8cdd |
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/* * maze * * Advanced Rogue * Copyright (C) 1984, 1985 Michael Morgan, Ken Dalka and AT&T * All rights reserved. * * Based on "Super-Rogue" * Copyright (C) 1984 Robert D. Kindelberger * All rights reserved. * * See the file LICENSE.TXT for full copyright and licensing information. */ #include <stdlib.h> #include "curses.h" #include "rogue.h" struct cell { char y_pos; char x_pos; }; struct bordercells { char num_pos; /* number of frontier cells next to you */ struct cell conn[4]; /* the y,x position of above cell */ } border_cells; static char *frontier, *bits; static int maze_lines, maze_cols; void draw_maze(void); int findcells(int y, int x); char *foffset(int y, int x); char *moffset(int y, int x); void rmwall(int newy, int newx, int oldy, int oldx); /* * crankout: * Does actual drawing of maze to window */ void crankout(void) { reg 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); } } } /* * domaze: * Draw the maze on this level. */ void do_maze(void) { reg int least; reg struct room *rp; reg struct linked_list *item; reg struct object *obj; int cnt; bool treas; coord tp; for (rp = rooms; rp < &rooms[MAXROOMS]; rp++) { rp->r_flags = ISGONE; /* kill all rooms */ rp->r_fires = NULL; /* 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) + 1); /* add in one large hunk */ attach(lvl_obj, item); cnt = 0; do { rnd_pos(rp, &tp); } until (mvinch(tp.y, tp.x) == FLOOR || cnt++ > 5000); mvaddch(tp.y, tp.x, GOLD); obj->o_pos = tp; /* * add in some food to make sure he has enough */ item = spec_item(FOOD, 0, 0, 0); obj = OBJPTR(item); attach(lvl_obj, item); do { rnd_pos(rp, &tp); } until (mvinch(tp.y, tp.x) == FLOOR || cnt++ > 5000); mvaddch(tp.y, tp.x, FOOD); obj->o_pos = tp; if (rnd(100) < 10) { /* 10% for treasure maze */ treas = TRUE; least = 6; debug("treasure maze"); } else { /* normal maze level */ least = 1; treas = FALSE; } genmonsters(least, treas); } /* * draw_maze: * Generate and draw the maze on the screen */ void draw_maze(void) { reg int i, j, more; reg char *ptr; maze_lines = (LINES - 3) / 2; maze_cols = (COLS - 1) / 2; bits = ALLOC((LINES - 3) * (COLS - 1)); frontier = ALLOC(maze_lines * maze_cols); ptr = frontier; while (ptr < (frontier + (maze_lines * maze_cols))) *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 < maze_lines; i++) { for (j = 0; j < maze_cols; j++) { do more = findcells(i,j); while(more != 0); } } crankout(); FREE(frontier); FREE(bits); } /* * findcells: * Figure out cells to open up */ int findcells(int y, int x) { reg int rtpos, i; *foffset(y, x) = FALSE; border_cells.num_pos = 0; if (y < maze_lines - 1) { /* look below */ if (*foffset(y + 1, x)) { border_cells.conn[border_cells.num_pos].y_pos = y + 1; border_cells.conn[border_cells.num_pos].x_pos = x; border_cells.num_pos += 1; } } if (y > 0) { /* look above */ if (*foffset(y - 1, x)) { border_cells.conn[border_cells.num_pos].y_pos = y - 1; border_cells.conn[border_cells.num_pos].x_pos = x; border_cells.num_pos += 1; } } if (x < maze_cols - 1) { /* look right */ if (*foffset(y, x + 1)) { border_cells.conn[border_cells.num_pos].y_pos = y; border_cells.conn[border_cells.num_pos].x_pos = x + 1; border_cells.num_pos += 1; } } if (x > 0) { /* look left */ if (*foffset(y, x - 1)) { border_cells.conn[border_cells.num_pos].y_pos = y; border_cells.conn[border_cells.num_pos].x_pos = x - 1; border_cells.num_pos += 1; } } if (border_cells.num_pos == 0) /* no neighbors available */ return 0; else { i = rnd(border_cells.num_pos); rtpos = border_cells.num_pos - 1; rmwall(border_cells.conn[i].y_pos, border_cells.conn[i].x_pos, y, x); return rtpos; } } /* * foffset: * Calculate memory address for frontier */ char * foffset(int y, int x) { return (frontier + (y * maze_cols) + x); } /* * Maze_view: * Returns true if the player can see the specified location within * the confines of a maze (within one column or row) */ bool maze_view(int y, int x) { register int start, goal, delta, ycheck = 0, xcheck = 0, absy, absx, see_radius; register bool row; char ch; /* What we are standing on (or near) */ /* Get the absolute value of y and x differences */ absy = hero.y - y; absx = hero.x - x; if (absy < 0) absy = -absy; if (absx < 0) absx = -absx; /* If we are standing in a wall, we can see a bit more */ switch (ch = CCHAR( winat(hero.y, hero.x) )) { case '|': case '-': case WALL: case SECRETDOOR: case DOOR: see_radius = 2; otherwise: see_radius = 1; } /* Must be within one or two rows or columns */ if (absy > see_radius && absx > see_radius) return(FALSE); if (absx > see_radius) { /* Go along row */ start = hero.x; goal = x; ycheck = hero.y; row = TRUE; } else { /* Go along column */ start = hero.y; goal = y; xcheck = hero.x; row = FALSE; } if (start <= goal) delta = 1; else delta = -1; /* Start one past where we are standing */ if (start != goal) start += delta; /* If we are in a wall, we want to look in the area outside the wall */ if (see_radius > 1) { if (row) { /* See if above us it okay first */ switch (winat(ycheck, start)) { case '|': case '-': case WALL: case DOOR: case SECRETDOOR: /* No good, try one up */ if (y > hero.y) ycheck++; else ycheck--; otherwise: see_radius = 1; /* Just look straight over the row */ } } else { /* See if above us it okay first */ switch (winat(start, xcheck)) { case '|': case '-': case WALL: case DOOR: case SECRETDOOR: /* No good, try one over */ if (x > hero.x) xcheck++; else xcheck--; otherwise: see_radius = 1; /* Just look straight up the column */ } } } /* Check boundary again */ if (absy > see_radius && absx > see_radius) return(FALSE); while (start != goal) { if (row) xcheck = start; else ycheck = start; switch (winat(ycheck, xcheck)) { case '|': case '-': case WALL: case DOOR: case SECRETDOOR: return(FALSE); } start += delta; } return(TRUE); } /* * moffset: * Calculate memory address for bits */ char * moffset(int y, int x) { return (bits + (y * (COLS - 1)) + x); } /* * rmwall: * Removes appropriate walls from the maze */ void rmwall(int newy, int newx, int oldy, int oldx) { reg int xdif,ydif; xdif = newx - oldx; ydif = newy - oldy; *moffset((oldy * 2) + ydif + 1, (oldx * 2) + xdif + 1) = FALSE; findcells(newy, newx); }