Complete Roguelike Tutorial, using python+libtcod, part 6 code
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This is part of the code for a series of tutorials; the main page can be found here. This part of the tutorial has been converted to use libctod version 1.5.1, but later parts still use 1.5.0. If you wish to follow the complete tutorial, you probably want the old version here |
AI
import libtcodpy as libtcod
import math
#actual size of the window
SCREEN_WIDTH = 80
SCREEN_HEIGHT = 50
#size of the map
MAP_WIDTH = 80
MAP_HEIGHT = 45
#parameters for dungeon generator
ROOM_MAX_SIZE = 10
ROOM_MIN_SIZE = 6
MAX_ROOMS = 30
MAX_ROOM_MONSTERS = 3
FOV_ALGO = 0 #default FOV algorithm
FOV_LIGHT_WALLS = True #light walls or not
TORCH_RADIUS = 10
LIMIT_FPS = 20 #20 frames-per-second maximum
color_dark_wall = libtcod.Color(0, 0, 100)
color_light_wall = libtcod.Color(130, 110, 50)
color_dark_ground = libtcod.Color(50, 50, 150)
color_light_ground = libtcod.Color(200, 180, 50)
class Tile:
#a tile of the map and its properties
def __init__(self, blocked, block_sight = None):
self.blocked = blocked
#all tiles start unexplored
self.explored = False
#by default, if a tile is blocked, it also blocks sight
if block_sight is None: block_sight = blocked
self.block_sight = block_sight
class Rect:
#a rectangle on the map. used to characterize a room.
def __init__(self, x, y, w, h):
self.x1 = x
self.y1 = y
self.x2 = x + w
self.y2 = y + h
def center(self):
center_x = (self.x1 + self.x2) / 2
center_y = (self.y1 + self.y2) / 2
return (center_x, center_y)
def intersect(self, other):
#returns true if this rectangle intersects with another one
return (self.x1 <= other.x2 and self.x2 >= other.x1 and
self.y1 <= other.y2 and self.y2 >= other.y1)
class Object:
#this is a generic object: the player, a monster, an item, the stairs...
#it's always represented by a character on screen.
def __init__(self, x, y, char, name, color, blocks=False, fighter=None, ai=None):
self.x = x
self.y = y
self.char = char
self.name = name
self.color = color
self.blocks = blocks
self.fighter = fighter
if self.fighter: #let the fighter component know who owns it
self.fighter.owner = self
self.ai = ai
if self.ai: #let the AI component know who owns it
self.ai.owner = self
def move(self, dx, dy):
#move by the given amount, if the destination is not blocked
if not is_blocked(self.x + dx, self.y + dy):
self.x += dx
self.y += dy
def move_towards(self, target_x, target_y):
#vector from this object to the target, and distance
dx = target_x - self.x
dy = target_y - self.y
distance = math.sqrt(dx ** 2 + dy ** 2)
#normalize it to length 1 (preserving direction), then round it and
#convert to integer so the movement is restricted to the map grid
dx = int(round(dx / distance))
dy = int(round(dy / distance))
self.move(dx, dy)
def distance_to(self, other):
#return the distance to another object
dx = other.x - self.x
dy = other.y - self.y
return math.sqrt(dx ** 2 + dy ** 2)
def draw(self):
#only show if it's visible to the player
if libtcod.map_is_in_fov(fov_map, self.x, self.y):
#set the color and then draw the character that represents this object at its position
libtcod.console_set_default_foreground(con, self.color)
libtcod.console_put_char(con, self.x, self.y, self.char, libtcod.BKGND_NONE)
def clear(self):
#erase the character that represents this object
libtcod.console_put_char(con, self.x, self.y, ' ', libtcod.BKGND_NONE)
class Fighter:
#combat-related properties and methods (monster, player, NPC).
def __init__(self, hp, defense, power):
self.max_hp = hp
self.hp = hp
self.defense = defense
self.power = power
class BasicMonster:
#AI for a basic monster.
def take_turn(self):
#a basic monster takes its turn. if you can see it, it can see you
monster = self.owner
if libtcod.map_is_in_fov(fov_map, monster.x, monster.y):
#move towards player if far away
if monster.distance_to(player) >= 2:
monster.move_towards(player.x, player.y)
#close enough, attack! (if the player is still alive.)
elif player.fighter.hp > 0:
print 'The attack of the ' + monster.name + ' bounces off your shiny metal armor!'
def is_blocked(x, y):
#first test the map tile
if map[x][y].blocked:
return True
#now check for any blocking objects
for object in objects:
if object.blocks and object.x == x and object.y == y:
return True
return False
def create_room(room):
global map
#go through the tiles in the rectangle and make them passable
for x in range(room.x1 + 1, room.x2):
for y in range(room.y1 + 1, room.y2):
map[x][y].blocked = False
map[x][y].block_sight = False
def create_h_tunnel(x1, x2, y):
global map
#horizontal tunnel. min() and max() are used in case x1>x2
for x in range(min(x1, x2), max(x1, x2) + 1):
map[x][y].blocked = False
map[x][y].block_sight = False
def create_v_tunnel(y1, y2, x):
global map
#vertical tunnel
for y in range(min(y1, y2), max(y1, y2) + 1):
map[x][y].blocked = False
map[x][y].block_sight = False
def make_map():
global map, player
#fill map with "blocked" tiles
map = [[ Tile(True)
for y in range(MAP_HEIGHT) ]
for x in range(MAP_WIDTH) ]
rooms = []
num_rooms = 0
for r in range(MAX_ROOMS):
#random width and height
w = libtcod.random_get_int(0, ROOM_MIN_SIZE, ROOM_MAX_SIZE)
h = libtcod.random_get_int(0, ROOM_MIN_SIZE, ROOM_MAX_SIZE)
#random position without going out of the boundaries of the map
x = libtcod.random_get_int(0, 0, MAP_WIDTH - w - 1)
y = libtcod.random_get_int(0, 0, MAP_HEIGHT - h - 1)
#"Rect" class makes rectangles easier to work with
new_room = Rect(x, y, w, h)
#run through the other rooms and see if they intersect with this one
failed = False
for other_room in rooms:
if new_room.intersect(other_room):
failed = True
break
if not failed:
#this means there are no intersections, so this room is valid
#"paint" it to the map's tiles
create_room(new_room)
#add some contents to this room, such as monsters
place_objects(new_room)
#center coordinates of new room, will be useful later
(new_x, new_y) = new_room.center()
if num_rooms == 0:
#this is the first room, where the player starts at
player.x = new_x
player.y = new_y
else:
#all rooms after the first:
#connect it to the previous room with a tunnel
#center coordinates of previous room
(prev_x, prev_y) = rooms[num_rooms-1].center()
#draw a coin (random number that is either 0 or 1)
if libtcod.random_get_int(0, 0, 1) == 1:
#first move horizontally, then vertically
create_h_tunnel(prev_x, new_x, prev_y)
create_v_tunnel(prev_y, new_y, new_x)
else:
#first move vertically, then horizontally
create_v_tunnel(prev_y, new_y, prev_x)
create_h_tunnel(prev_x, new_x, new_y)
#finally, append the new room to the list
rooms.append(new_room)
num_rooms += 1
def place_objects(room):
#choose random number of monsters
num_monsters = libtcod.random_get_int(0, 0, MAX_ROOM_MONSTERS)
for i in range(num_monsters):
#choose random spot for this monster
x = libtcod.random_get_int(0, room.x1, room.x2)
y = libtcod.random_get_int(0, room.y1, room.y2)
#only place it if the tile is not blocked
if not is_blocked(x, y):
if libtcod.random_get_int(0, 0, 100) < 80: #80% chance of getting an orc
#create an orc
fighter_component = Fighter(hp=10, defense=0, power=3)
ai_component = BasicMonster()
monster = Object(x, y, 'o', 'orc', libtcod.desaturated_green,
blocks=True, fighter=fighter_component, ai=ai_component)
else:
#create a troll
fighter_component = Fighter(hp=16, defense=1, power=4)
ai_component = BasicMonster()
monster = Object(x, y, 'T', 'troll', libtcod.darker_green,
blocks=True, fighter=fighter_component, ai=ai_component)
objects.append(monster)
def render_all():
global fov_map, color_dark_wall, color_light_wall
global color_dark_ground, color_light_ground
global fov_recompute
if fov_recompute:
#recompute FOV if needed (the player moved or something)
fov_recompute = False
libtcod.map_compute_fov(fov_map, player.x, player.y, TORCH_RADIUS, FOV_LIGHT_WALLS, FOV_ALGO)
#go through all tiles, and set their background color according to the FOV
for y in range(MAP_HEIGHT):
for x in range(MAP_WIDTH):
visible = libtcod.map_is_in_fov(fov_map, x, y)
wall = map[x][y].block_sight
if not visible:
#if it's not visible right now, the player can only see it if it's explored
if map[x][y].explored:
if wall:
libtcod.console_set_char_background(con, x, y, color_dark_wall, libtcod.BKGND_SET)
else:
libtcod.console_set_char_background(con, x, y, color_dark_ground, libtcod.BKGND_SET)
else:
#it's visible
if wall:
libtcod.console_set_char_background(con, x, y, color_light_wall, libtcod.BKGND_SET )
else:
libtcod.console_set_char_background(con, x, y, color_light_ground, libtcod.BKGND_SET )
#since it's visible, explore it
map[x][y].explored = True
#draw all objects in the list
for object in objects:
object.draw()
#blit the contents of "con" to the root console
libtcod.console_blit(con, 0, 0, SCREEN_WIDTH, SCREEN_HEIGHT, 0, 0, 0)
def player_move_or_attack(dx, dy):
global fov_recompute
#the coordinates the player is moving to/attacking
x = player.x + dx
y = player.y + dy
#try to find an attackable object there
target = None
for object in objects:
if object.x == x and object.y == y:
target = object
break
#attack if target found, move otherwise
if target is not None:
print 'The ' + target.name + ' laughs at your puny efforts to attack him!'
else:
player.move(dx, dy)
fov_recompute = True
def handle_keys():
#key = libtcod.console_check_for_keypress() #real-time
key = libtcod.console_wait_for_keypress(True) #turn-based
if key.vk == libtcod.KEY_ENTER and key.lalt:
#Alt+Enter: toggle fullscreen
libtcod.console_set_fullscreen(not libtcod.console_is_fullscreen())
elif key.vk == libtcod.KEY_ESCAPE:
return 'exit' #exit game
if game_state == 'playing':
#movement keys
if libtcod.console_is_key_pressed(libtcod.KEY_UP):
player_move_or_attack(0, -1)
elif libtcod.console_is_key_pressed(libtcod.KEY_DOWN):
player_move_or_attack(0, 1)
elif libtcod.console_is_key_pressed(libtcod.KEY_LEFT):
player_move_or_attack(-1, 0)
elif libtcod.console_is_key_pressed(libtcod.KEY_RIGHT):
player_move_or_attack(1, 0)
else:
return 'didnt-take-turn'
#############################################
# Initialization & Main Loop
#############################################
libtcod.console_set_custom_font('arial10x10.png', libtcod.FONT_TYPE_GREYSCALE | libtcod.FONT_LAYOUT_TCOD)
libtcod.console_init_root(SCREEN_WIDTH, SCREEN_HEIGHT, 'python/libtcod tutorial', False)
libtcod.sys_set_fps(LIMIT_FPS)
con = libtcod.console_new(SCREEN_WIDTH, SCREEN_HEIGHT)
#create object representing the player
fighter_component = Fighter(hp=30, defense=2, power=5)
player = Object(0, 0, '@', 'player', libtcod.white, blocks=True, fighter=fighter_component)
#the list of objects with just the player
objects = [player]
#generate map (at this point it's not drawn to the screen)
make_map()
#create the FOV map, according to the generated map
fov_map = libtcod.map_new(MAP_WIDTH, MAP_HEIGHT)
for y in range(MAP_HEIGHT):
for x in range(MAP_WIDTH):
libtcod.map_set_properties(fov_map, x, y, not map[x][y].block_sight, not map[x][y].blocked)
fov_recompute = True
game_state = 'playing'
player_action = None
while not libtcod.console_is_window_closed():
#render the screen
render_all()
libtcod.console_flush()
#erase all objects at their old locations, before they move
for object in objects:
object.clear()
#handle keys and exit game if needed
player_action = handle_keys()
if player_action == 'exit':
break
#let monsters take their turn
if game_state == 'playing' and player_action != 'didnt-take-turn':
for object in objects:
if object.ai:
object.ai.take_turn()
Untimely deaths
import libtcodpy as libtcod
import math
#actual size of the window
SCREEN_WIDTH = 80
SCREEN_HEIGHT = 50
#size of the map
MAP_WIDTH = 80
MAP_HEIGHT = 45
#parameters for dungeon generator
ROOM_MAX_SIZE = 10
ROOM_MIN_SIZE = 6
MAX_ROOMS = 30
MAX_ROOM_MONSTERS = 3
FOV_ALGO = 0 #default FOV algorithm
FOV_LIGHT_WALLS = True #light walls or not
TORCH_RADIUS = 10
LIMIT_FPS = 20 #20 frames-per-second maximum
color_dark_wall = libtcod.Color(0, 0, 100)
color_light_wall = libtcod.Color(130, 110, 50)
color_dark_ground = libtcod.Color(50, 50, 150)
color_light_ground = libtcod.Color(200, 180, 50)
class Tile:
#a tile of the map and its properties
def __init__(self, blocked, block_sight = None):
self.blocked = blocked
#all tiles start unexplored
self.explored = False
#by default, if a tile is blocked, it also blocks sight
if block_sight is None: block_sight = blocked
self.block_sight = block_sight
class Rect:
#a rectangle on the map. used to characterize a room.
def __init__(self, x, y, w, h):
self.x1 = x
self.y1 = y
self.x2 = x + w
self.y2 = y + h
def center(self):
center_x = (self.x1 + self.x2) / 2
center_y = (self.y1 + self.y2) / 2
return (center_x, center_y)
def intersect(self, other):
#returns true if this rectangle intersects with another one
return (self.x1 <= other.x2 and self.x2 >= other.x1 and
self.y1 <= other.y2 and self.y2 >= other.y1)
class Object:
#this is a generic object: the player, a monster, an item, the stairs...
#it's always represented by a character on screen.
def __init__(self, x, y, char, name, color, blocks=False, fighter=None, ai=None):
self.x = x
self.y = y
self.char = char
self.name = name
self.color = color
self.blocks = blocks
self.fighter = fighter
if self.fighter: #let the fighter component know who owns it
self.fighter.owner = self
self.ai = ai
if self.ai: #let the AI component know who owns it
self.ai.owner = self
def move(self, dx, dy):
#move by the given amount, if the destination is not blocked
if not is_blocked(self.x + dx, self.y + dy):
self.x += dx
self.y += dy
def move_towards(self, target_x, target_y):
#vector from this object to the target, and distance
dx = target_x - self.x
dy = target_y - self.y
distance = math.sqrt(dx ** 2 + dy ** 2)
#normalize it to length 1 (preserving direction), then round it and
#convert to integer so the movement is restricted to the map grid
dx = int(round(dx / distance))
dy = int(round(dy / distance))
self.move(dx, dy)
def distance_to(self, other):
#return the distance to another object
dx = other.x - self.x
dy = other.y - self.y
return math.sqrt(dx ** 2 + dy ** 2)
def send_to_back(self):
#make this object be drawn first, so all others appear above it if they're in the same tile.
global objects
objects.remove(self)
objects.insert(0, self)
def draw(self):
#only show if it's visible to the player
if libtcod.map_is_in_fov(fov_map, self.x, self.y):
#set the color and then draw the character that represents this object at its position
libtcod.console_set_default_foreground(con, self.color)
libtcod.console_put_char(con, self.x, self.y, self.char, libtcod.BKGND_NONE)
def clear(self):
#erase the character that represents this object
libtcod.console_put_char(con, self.x, self.y, ' ', libtcod.BKGND_NONE)
class Fighter:
#combat-related properties and methods (monster, player, NPC).
def __init__(self, hp, defense, power, death_function=None):
self.max_hp = hp
self.hp = hp
self.defense = defense
self.power = power
self.death_function = death_function
def attack(self, target):
#a simple formula for attack damage
damage = self.power - target.fighter.defense
if damage > 0:
#make the target take some damage
print self.owner.name.capitalize() + ' attacks ' + target.name + ' for ' + str(damage) + ' hit points.'
target.fighter.take_damage(damage)
else:
print self.owner.name.capitalize() + ' attacks ' + target.name + ' but it has no effect!'
def take_damage(self, damage):
#apply damage if possible
if damage > 0:
self.hp -= damage
#check for death. if there's a death function, call it
if self.hp <= 0:
function = self.death_function
if function is not None:
function(self.owner)
class BasicMonster:
#AI for a basic monster.
def take_turn(self):
#a basic monster takes its turn. if you can see it, it can see you
monster = self.owner
if libtcod.map_is_in_fov(fov_map, monster.x, monster.y):
#move towards player if far away
if monster.distance_to(player) >= 2:
monster.move_towards(player.x, player.y)
#close enough, attack! (if the player is still alive.)
elif player.fighter.hp > 0:
monster.fighter.attack(player)
def is_blocked(x, y):
#first test the map tile
if map[x][y].blocked:
return True
#now check for any blocking objects
for object in objects:
if object.blocks and object.x == x and object.y == y:
return True
return False
def create_room(room):
global map
#go through the tiles in the rectangle and make them passable
for x in range(room.x1 + 1, room.x2):
for y in range(room.y1 + 1, room.y2):
map[x][y].blocked = False
map[x][y].block_sight = False
def create_h_tunnel(x1, x2, y):
global map
#horizontal tunnel. min() and max() are used in case x1>x2
for x in range(min(x1, x2), max(x1, x2) + 1):
map[x][y].blocked = False
map[x][y].block_sight = False
def create_v_tunnel(y1, y2, x):
global map
#vertical tunnel
for y in range(min(y1, y2), max(y1, y2) + 1):
map[x][y].blocked = False
map[x][y].block_sight = False
def make_map():
global map, player
#fill map with "blocked" tiles
map = [[ Tile(True)
for y in range(MAP_HEIGHT) ]
for x in range(MAP_WIDTH) ]
rooms = []
num_rooms = 0
for r in range(MAX_ROOMS):
#random width and height
w = libtcod.random_get_int(0, ROOM_MIN_SIZE, ROOM_MAX_SIZE)
h = libtcod.random_get_int(0, ROOM_MIN_SIZE, ROOM_MAX_SIZE)
#random position without going out of the boundaries of the map
x = libtcod.random_get_int(0, 0, MAP_WIDTH - w - 1)
y = libtcod.random_get_int(0, 0, MAP_HEIGHT - h - 1)
#"Rect" class makes rectangles easier to work with
new_room = Rect(x, y, w, h)
#run through the other rooms and see if they intersect with this one
failed = False
for other_room in rooms:
if new_room.intersect(other_room):
failed = True
break
if not failed:
#this means there are no intersections, so this room is valid
#"paint" it to the map's tiles
create_room(new_room)
#add some contents to this room, such as monsters
place_objects(new_room)
#center coordinates of new room, will be useful later
(new_x, new_y) = new_room.center()
if num_rooms == 0:
#this is the first room, where the player starts at
player.x = new_x
player.y = new_y
else:
#all rooms after the first:
#connect it to the previous room with a tunnel
#center coordinates of previous room
(prev_x, prev_y) = rooms[num_rooms-1].center()
#draw a coin (random number that is either 0 or 1)
if libtcod.random_get_int(0, 0, 1) == 1:
#first move horizontally, then vertically
create_h_tunnel(prev_x, new_x, prev_y)
create_v_tunnel(prev_y, new_y, new_x)
else:
#first move vertically, then horizontally
create_v_tunnel(prev_y, new_y, prev_x)
create_h_tunnel(prev_x, new_x, new_y)
#finally, append the new room to the list
rooms.append(new_room)
num_rooms += 1
def place_objects(room):
#choose random number of monsters
num_monsters = libtcod.random_get_int(0, 0, MAX_ROOM_MONSTERS)
for i in range(num_monsters):
#choose random spot for this monster
x = libtcod.random_get_int(0, room.x1, room.x2)
y = libtcod.random_get_int(0, room.y1, room.y2)
#only place it if the tile is not blocked
if not is_blocked(x, y):
if libtcod.random_get_int(0, 0, 100) < 80: #80% chance of getting an orc
#create an orc
fighter_component = Fighter(hp=10, defense=0, power=3, death_function=monster_death)
ai_component = BasicMonster()
monster = Object(x, y, 'o', 'orc', libtcod.desaturated_green,
blocks=True, fighter=fighter_component, ai=ai_component)
else:
#create a troll
fighter_component = Fighter(hp=16, defense=1, power=4, death_function=monster_death)
ai_component = BasicMonster()
monster = Object(x, y, 'T', 'troll', libtcod.darker_green,
blocks=True, fighter=fighter_component, ai=ai_component)
objects.append(monster)
def render_all():
global fov_map, color_dark_wall, color_light_wall
global color_dark_ground, color_light_ground
global fov_recompute
if fov_recompute:
#recompute FOV if needed (the player moved or something)
fov_recompute = False
libtcod.map_compute_fov(fov_map, player.x, player.y, TORCH_RADIUS, FOV_LIGHT_WALLS, FOV_ALGO)
#go through all tiles, and set their background color according to the FOV
for y in range(MAP_HEIGHT):
for x in range(MAP_WIDTH):
visible = libtcod.map_is_in_fov(fov_map, x, y)
wall = map[x][y].block_sight
if not visible:
#if it's not visible right now, the player can only see it if it's explored
if map[x][y].explored:
if wall:
libtcod.console_set_char_background(con, x, y, color_dark_wall, libtcod.BKGND_SET)
else:
libtcod.console_set_char_background(con, x, y, color_dark_ground, libtcod.BKGND_SET)
else:
#it's visible
if wall:
libtcod.console_set_char_background(con, x, y, color_light_wall, libtcod.BKGND_SET )
else:
libtcod.console_set_char_background(con, x, y, color_light_ground, libtcod.BKGND_SET )
#since it's visible, explore it
map[x][y].explored = True
#draw all objects in the list, except the player. we want it to
#always appear over all other objects! so it's drawn later.
for object in objects:
if object != player:
object.draw()
player.draw()
#blit the contents of "con" to the root console
libtcod.console_blit(con, 0, 0, SCREEN_WIDTH, SCREEN_HEIGHT, 0, 0, 0)
#show the player's stats
libtcod.console_set_default_foreground(con, libtcod.white)
libtcod.console_print_ex(0, 1, SCREEN_HEIGHT - 2, libtcod.BKGND_NONE, libtcod.LEFT,
'HP: ' + str(player.fighter.hp) + '/' + str(player.fighter.max_hp))
def player_move_or_attack(dx, dy):
global fov_recompute
#the coordinates the player is moving to/attacking
x = player.x + dx
y = player.y + dy
#try to find an attackable object there
target = None
for object in objects:
if object.fighter and object.x == x and object.y == y:
target = object
break
#attack if target found, move otherwise
if target is not None:
player.fighter.attack(target)
else:
player.move(dx, dy)
fov_recompute = True
def handle_keys():
#key = libtcod.console_check_for_keypress() #real-time
key = libtcod.console_wait_for_keypress(True) #turn-based
if key.vk == libtcod.KEY_ENTER and key.lalt:
#Alt+Enter: toggle fullscreen
libtcod.console_set_fullscreen(not libtcod.console_is_fullscreen())
elif key.vk == libtcod.KEY_ESCAPE:
return 'exit' #exit game
if game_state == 'playing':
#movement keys
if libtcod.console_is_key_pressed(libtcod.KEY_UP):
player_move_or_attack(0, -1)
elif libtcod.console_is_key_pressed(libtcod.KEY_DOWN):
player_move_or_attack(0, 1)
elif libtcod.console_is_key_pressed(libtcod.KEY_LEFT):
player_move_or_attack(-1, 0)
elif libtcod.console_is_key_pressed(libtcod.KEY_RIGHT):
player_move_or_attack(1, 0)
else:
return 'didnt-take-turn'
def player_death(player):
#the game ended!
global game_state
print 'You died!'
game_state = 'dead'
#for added effect, transform the player into a corpse!
player.char = '%'
player.color = libtcod.dark_red
def monster_death(monster):
#transform it into a nasty corpse! it doesn't block, can't be
#attacked and doesn't move
print monster.name.capitalize() + ' is dead!'
monster.char = '%'
monster.color = libtcod.dark_red
monster.blocks = False
monster.fighter = None
monster.ai = None
monster.name = 'remains of ' + monster.name
monster.send_to_back()
#############################################
# Initialization & Main Loop
#############################################
libtcod.console_set_custom_font('arial10x10.png', libtcod.FONT_TYPE_GREYSCALE | libtcod.FONT_LAYOUT_TCOD)
libtcod.console_init_root(SCREEN_WIDTH, SCREEN_HEIGHT, 'python/libtcod tutorial', False)
libtcod.sys_set_fps(LIMIT_FPS)
con = libtcod.console_new(SCREEN_WIDTH, SCREEN_HEIGHT)
#create object representing the player
fighter_component = Fighter(hp=30, defense=2, power=5, death_function=player_death)
player = Object(0, 0, '@', 'player', libtcod.white, blocks=True, fighter=fighter_component)
#the list of objects with just the player
objects = [player]
#generate map (at this point it's not drawn to the screen)
make_map()
#create the FOV map, according to the generated map
fov_map = libtcod.map_new(MAP_WIDTH, MAP_HEIGHT)
for y in range(MAP_HEIGHT):
for x in range(MAP_WIDTH):
libtcod.map_set_properties(fov_map, x, y, not map[x][y].block_sight, not map[x][y].blocked)
fov_recompute = True
game_state = 'playing'
player_action = None
while not libtcod.console_is_window_closed():
#render the screen
render_all()
libtcod.console_flush()
#erase all objects at their old locations, before they move
for object in objects:
object.clear()
#handle keys and exit game if needed
player_action = handle_keys()
if player_action == 'exit':
break
#let monsters take their turn
if game_state == 'playing' and player_action != 'didnt-take-turn':
for object in objects:
if object.ai:
object.ai.take_turn()