Mercurial > hg > early-roguelike
view arogue5/maze.c @ 195:beab22b087a1
Advanced Rogue 5: initialize some variables.
author | John "Elwin" Edwards |
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date | Tue, 11 Aug 2015 13:13:08 -0400 |
parents | 0ed67132cf10 |
children | 56e748983fa8 |
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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; char *moffset(), *foffset(); /* * crankout: * Does actual drawing of maze to window */ crankout() { 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. */ do_maze() { 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, NULL, NULL, NULL); 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, NULL, NULL, NULL); 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 */ draw_maze() { 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 */ findcells(y,x) reg int x, y; { 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(y, x) int y, 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(y, x) int y, 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(y, x) int y, x; { return (bits + (y * (COLS - 1)) + x); } /* * rmwall: * Removes appropriate walls from the maze */ rmwall(newy, newx, oldy, oldx) int newy, newx, oldy, oldx; { reg int xdif,ydif; xdif = newx - oldx; ydif = newy - oldy; *moffset((oldy * 2) + ydif + 1, (oldx * 2) + xdif + 1) = FALSE; findcells(newy, newx); }