So I've been trying to recreate the PacMan Game, I have been stuck on how to approach the idea of the Ghosts moving around the maze, I've heard of A* and Dijkstra's Algorithms, but is there a simpler way to implement ghosts moving around the maze? Aside from figuring out the different modes they can go into, Frightened, Chase, and Scatter, I just want to be able to understand whats the best way to get them to move randomly in the maze with the wall detection function in place.
import pygame
import time
#import random
import pickle
import math
pygame.init()
pygame.mixer.init()
pygame.display.set_caption("Pac-Man")
# Sets the size of the screen via (WIDTH, HEIGHT)
SCREEN_WIDTH = 478
SCREEN_HEIGHT = 608
# Speed of Characters
SPEED = 1
# Frames per second, how fast the game runs
FPS = 50
# Colors (RED,GREEN,BLUE)
BLACK = (0, 0, 0)
WHITE = (255, 255, 255)
YELLOW = (255, 255, 0)
BLUE = (0, 0, 255)
# Sets the WIDTH and HEIGHT of the window
WINDOW = (SCREEN_WIDTH, SCREEN_HEIGHT)
# Displays the screen
SCREEN = pygame.display.set_mode(WINDOW)
CLOCK = pygame.time.Clock()
PacManStartSurface = pygame.transform.scale(pygame.image.load
("PacManStart.png"), (23, 23))
PacManStartSurface.convert()
PacManStartRect = PacManStartSurface.get_rect(topleft =
(((SCREEN_WIDTH - 25) // 2),
(SCREEN_HEIGHT + 144) // 2))
PacManSurface = pygame.transform.scale(pygame.image.load
("PacManRight.png"), (23, 23))
PacManSurface.convert()
PacManRect = PacManStartSurface.get_rect(topleft =
(((SCREEN_WIDTH - 125) // 2),
(SCREEN_HEIGHT + 144) // 2))
CurrentSurface = PacManStartSurface
CurrentRect = PacManStartRect
BackgroundSurface = pygame.image.load("Background.png").convert()
PinkGhostSurface = pygame.transform.scale(pygame.image.load("PinkGhost.png")
.convert(), (23, 23))
PinkGhostRect = PinkGhostSurface.get_rect()
YellowGhostSurface = pygame.transform.scale(pygame.image.load
("YellowGhost.png")
.convert(), (23, 23))
YellowGhostRect = YellowGhostSurface.get_rect()
RedGhostSurface = pygame.transform.scale(pygame.image.load("RedGhost.png")
.convert(), (23, 23))
RedGhostRect = RedGhostSurface.get_rect()
BlueGhostSurface = pygame.transform.scale(pygame.image.load("BlueGhost.png")
.convert(), (23, 23))
BlueGhostRect = BlueGhostSurface.get_rect()
pygame.mixer.music.load('power_pellet.wav')
Font = pygame.font.Font("emulogic.ttf", 15)
class PacMan():
def __init__(self):
self.LIVES = 3
class Maze():
def __init__(self):
self.DOTS = []
self.WALLS = []
self.ENERGIZER = []
self.GHOSTS = []
self.DECISION_NODES = []
self.BLOCK_WIDTH = 25
self.BLOCK_HEIGHT = 25
self.MAZE_OFFSET_X = 0
self.MAZE_OFFSET_Y = 50
self.MARGIN = 3
# 0 - Dots
# 1 - Walls
# 2 - Energizers
# 3 - Empty Spaces
# 4 - Ghosts
# 5 - Decision Nodes & will be added for intersections in maze
self.MATRIX = [1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1], \
[1,0,0,0,0,0,0,0,0,1,0,0,0,0,0,0,0,0,1], \
[1,2,1,1,0,1,1,1,0,1,0,1,1,1,0,1,1,2,1], \
[1,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,1], \
[1,0,1,1,0,1,0,1,1,1,1,1,0,1,0,1,1,0,1], \
[1,0,0,0,0,1,0,0,0,1,0,0,0,1,0,0,0,0,1], \
[1,1,1,1,0,1,1,1,3,1,3,1,1,1,0,1,1,1,1], \
[3,3,3,1,0,1,3,3,5,4,5,3,3,1,0,1,3,3,3], \
[1,1,1,1,0,1,3,1,1,1,1,1,3,1,0,1,1,1,1], \
[0,0,0,0,0,3,5,1,4,4,4,1,5,3,0,0,0,0,0], \
[1,1,1,1,0,1,3,1,1,1,1,1,3,1,0,1,1,1,1], \
[3,3,3,1,0,1,5,3,3,3,3,3,5,1,0,1,3,3,3], \
[1,1,1,1,0,1,3,1,1,1,1,1,3,1,0,1,1,1,1], \
[1,0,0,0,0,0,0,0,0,1,0,0,0,0,0,0,0,0,1], \
[1,2,1,1,0,1,1,1,0,1,0,1,1,1,0,1,1,2,1], \
[1,0,0,1,0,0,0,0,0,3,0,0,0,0,0,1,0,0,1], \
[1,1,0,1,0,1,0,1,1,1,1,1,0,1,0,1,0,1,1], \
[1,0,0,0,0,1,0,0,0,1,0,0,0,1,0,0,0,0,1], \
[1,0,1,1,1,1,1,1,0,1,0,1,1,1,1,1,1,0,1], \
[1,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,1], \
[1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1]
# BackgroundImage(X, Y, WIDTH, HEIGHT)
self.MAZE_X = self.BLOCK_WIDTH * (len(self.MATRIX[0])
+ self.MAZE_OFFSET_X)
self.MAZE_Y = self.BLOCK_HEIGHT * (len(self.MATRIX)
+ self.MAZE_OFFSET_Y)
self.MAZE_WIDTH = self.BLOCK_WIDTH * len(self.MATRIX[0])
self.MAZE_HEIGHT = self.BLOCK_HEIGHT * len(self.MATRIX)
def DrawMaze(self, MazeSurface):
for ROW in range(len(self.MATRIX)):
for COLUMN in range(len(self.MATRIX[0])):
# Only saves the position of each dot
if self.MATRIX[ROW][COLUMN] == 0:
self.DOTS.append([(self.BLOCK_WIDTH * COLUMN),
(self.BLOCK_HEIGHT * ROW), 4, 4])
if self.MATRIX[ROW][COLUMN] == 1:
self.WALLS.append(pygame.draw.rect(MazeSurface, WHITE,
[((self.BLOCK_WIDTH) * COLUMN),
((self.BLOCK_HEIGHT) * ROW),
self.BLOCK_WIDTH, self.BLOCK_HEIGHT]))
if self.MATRIX[ROW][COLUMN] == 2:
self.ENERGIZER.append([(self.BLOCK_WIDTH * COLUMN),
(self.BLOCK_HEIGHT * ROW), 14, 14])
if self.MATRIX[ROW][COLUMN] == 4:
self.GHOSTS.append([(self.BLOCK_WIDTH * COLUMN),
(self.BLOCK_HEIGHT * ROW), 23, 23])
if self.MATRIX[ROW][COLUMN] == 5:
self.DECISION_NODES.append([(self.BLOCK_WIDTH * COLUMN),
(self.BLOCK_HEIGHT * ROW), 4, 4])
class Main(Maze):
def __init__(self):
# Inherits Maze class
Maze.__init__(self)
self.TimeBetweenBites = 0.1
self.LastBiteTime = time.time()
self.MouthOpen = False
self.PacManDirection = ""
self.GhostDirection = ""
self.PreviousGhostDirection = ""
self.SCORE = 0
self.HIGH_SCORE = 0
def PacManMovement(self):
key = pygame.key.get_pressed()
if key[pygame.K_LEFT] and not key[pygame.K_UP] \
and not key[pygame.K_DOWN]:
self.PacManDirection = "LEFT"
elif key[pygame.K_RIGHT] and not key[pygame.K_UP] \
and not key[pygame.K_DOWN]:
self.PacManDirection = "RIGHT"
elif key[pygame.K_UP] and not key[pygame.K_LEFT] \
and not key[pygame.K_RIGHT]:
self.PacManDirection = "UP"
elif key[pygame.K_DOWN] and not key[pygame.K_LEFT] \
and not key[pygame.K_RIGHT]:
self.PacManDirection = "DOWN"
def ContinuePacManMovement(self):
if self.PacManDirection == "LEFT":
CurrentRect.x -= SPEED
self.PacManWallDetection(-1, 0, CurrentRect)
if self.PacManDirection == "RIGHT":
CurrentRect.x += SPEED
self.PacManWallDetection(1, 0, CurrentRect)
if self.PacManDirection == "UP":
CurrentRect.y -= SPEED
self.PacManWallDetection(0, -1, CurrentRect)
if self.PacManDirection == "DOWN":
CurrentRect.y += SPEED
self.PacManWallDetection(0, 1, CurrentRect)
def PacManTeleport(self):
if CurrentRect.right < 0:
CurrentRect.right = SCREEN_WIDTH + 20
if CurrentRect.left > SCREEN_WIDTH:
CurrentRect.right = 0
def GhostTeleport(self):
if PinkGhostRect.right < 0:
PinkGhostRect.right = SCREEN_WIDTH + 20
if PinkGhostRect.left > SCREEN_WIDTH:
PinkGhostRect.right = 0
def PacManWallDetection(self, x, y, CurrentRect):
CurrentRect.right += x
for WALL in self.WALLS:
COLLIDE = CurrentRect.colliderect(WALL)
if COLLIDE:
if x < 0:
CurrentRect.left = WALL.right
CurrentSurface = pygame.transform.rotate(PacManSurface, 180)
MazeSurface.blit(CurrentSurface, CurrentRect)
if x > 0:
CurrentRect.right = WALL.left
break
CurrentRect.top += y
for WALL in self.WALLS:
COLLIDE = CurrentRect.colliderect(WALL)
if COLLIDE:
if y < 0:
CurrentRect.top = WALL.bottom
if y > 0:
CurrentRect.bottom = WALL.top
break
def GhostWallDetection(self, x, y, PinkGhostRect):
PinkGhostRect.right += x
for WALL in self.WALLS:
COLLIDE = PinkGhostRect.colliderect(WALL)
if COLLIDE:
if x < 0:
PinkGhostRect.left = WALL.right
if x > 0:
PinkGhostRect.right = WALL.left
break
PinkGhostRect.top += y
for WALL in self.WALLS:
COLLIDE = PinkGhostRect.colliderect(WALL)
if COLLIDE:
if y < 0:
PinkGhostRect.top = WALL.bottom
if y > 0:
PinkGhostRect.bottom = WALL.top
break
def EatDots(self):
for ROW in range(len(self.MATRIX)):
for COLUMN in range(len(self.MATRIX[0])):
for DOT in self.DOTS:
CHOMP = CurrentRect.colliderect(DOT)
if CHOMP:
Main.PlaySound(self, 0)
self.DOTS.remove(DOT)
self.MATRIX[ROW][COLUMN] = 3
self.SCORE += 10
if self.SCORE > self.HIGH_SCORE:
self.HIGH_SCORE = self.SCORE
return str(self.SCORE), str(self.HIGH_SCORE)
def EatEnergizer(self):
for ROW in range(len(self.MATRIX)):
for COLUMN in range(len(self.MATRIX[0])):
for POWERUP in self.ENERGIZER:
CHOMP = CurrentRect.colliderect(POWERUP)
if CHOMP:
self.ENERGIZER.remove(POWERUP)
self.MATRIX[ROW][COLUMN] = 3
self.SCORE += 50
Main.PlaySound(self, 1)
if self.SCORE > self.HIGH_SCORE:
self.HIGH_SCORE = self.SCORE
return str(self.SCORE), str(self.HIGH_SCORE)
def EatGhosts(self):
pass
def DrawDots(self):
for POSITION in self.DOTS:
X = POSITION[0] + 13
Y = POSITION[1] + 13
WIDTH = POSITION[2]
HEIGHT = POSITION[3]
pygame.draw.circle(MazeSurface, YELLOW, (X, Y),
WIDTH // 2, HEIGHT // 2)
def DrawEnergizer(self):
for POSITION in self.ENERGIZER:
X = POSITION[0] + 13
Y = POSITION[1] + 13
WIDTH = POSITION[2]
HEIGHT = POSITION[3]
pygame.draw.circle(MazeSurface, YELLOW, (X, Y),
WIDTH // 2, HEIGHT // 2)
def DrawGhosts(self):
MazeSurface.blit(PinkGhostSurface, PinkGhostRect)
MazeSurface.blit(YellowGhostSurface, YellowGhostRect)
MazeSurface.blit(RedGhostSurface, RedGhostRect)
MazeSurface.blit(BlueGhostSurface, BlueGhostRect)
def GhostPosition(self):
X, Y, WIDTH, HEIGHT = self.GHOSTS[0]
PinkGhostRect.x = X
PinkGhostRect.y = Y
PinkGhostRect.width = WIDTH
PinkGhostRect.height = HEIGHT
X, Y, WIDTH, HEIGHT = self.GHOSTS[1]
YellowGhostRect.x = X
YellowGhostRect.y = Y
YellowGhostRect.width = WIDTH
YellowGhostRect.height = HEIGHT
X, Y, WIDTH, HEIGHT = self.GHOSTS[2]
RedGhostRect.x = X
RedGhostRect.y = Y
RedGhostRect.width = WIDTH
RedGhostRect.height = HEIGHT
X, Y, WIDTH, HEIGHT = self.GHOSTS[3]
BlueGhostRect.x = X
BlueGhostRect.y = Y
BlueGhostRect.width = WIDTH
BlueGhostRect.height = HEIGHT
def ChaseMode(self):
self.GhostDirection = "LEFT"
self.GhostWallDetection(-1, 0, PinkGhostRect)
if PinkGhostRect.x < CurrentRect.x:
self.GhostDirection = "RIGHT"
self.GhostWallDetection(1, 0, PinkGhostRect)
if PinkGhostRect.y > CurrentRect.y:
self.GhostDirection = "UP"
self.GhostWallDetection(0, -1, PinkGhostRect)
if PinkGhostRect.y < CurrentRect.y:
self.GhostDirection = "DOWN"
self.GhostWallDetection(0, 1, PinkGhostRect)
def ScatterMode(self):
pass
def FrightenedMode(self):
pass
def PlaySound(self, Track):
if Track == 0:
Eat = pygame.mixer.Sound("pacman_chomp.wav")
Eat.play()
pygame.mixer.fadeout(400)
if Track == 1:
EatPellet = pygame.mixer.Sound("pacman_eatghost.wav")
EatPellet.play()
pygame.mixer.music.play(7)
pygame.mixer.fadeout(400)
def ShowScore(self):
global Font
OneUpText = Font.render("1UP", True, WHITE)
OneUpTextRect = OneUpText.get_rect(center = (70, 10))
# Displays current score
OneUpScoreText = Font.render(str(self.SCORE), True, WHITE)
OneUpScoreRect = OneUpScoreText.get_rect(center =
((SCREEN_WIDTH - 290)
// 2, 26))
HighScoreText = Font.render("High Score", True, WHITE)
HighScoreTextRect = HighScoreText.get_rect(center =
(SCREEN_WIDTH // 2, 10))
# Displays High Score
HighScoreNumber = Font.render(str(self.HIGH_SCORE), True, WHITE)
HighScoreNumberRect = HighScoreNumber.get_rect(center =
((SCREEN_WIDTH + 90)
// 2, 26))
SCREEN.blit(OneUpText, OneUpTextRect)
SCREEN.blit(OneUpScoreText, OneUpScoreRect)
SCREEN.blit(HighScoreText, HighScoreTextRect)
SCREEN.blit(HighScoreNumber, HighScoreNumberRect)
def PacManBite(self):
global CurrentSurface
CurrentTime = time.time()
if CurrentTime - self.LastBiteTime >= self.TimeBetweenBites:
self.LastBiteTime = CurrentTime
if self.MouthOpen:
CurrentSurface = PacManStartSurface
else:
CurrentSurface = PacManSurface
self.MouthOpen = not self.MouthOpen
if self.PacManDirection == "LEFT":
CurrentSurface = pygame.transform.rotate(CurrentSurface, 180)
if self.PacManDirection == "RIGHT":
CurrentSurface = CurrentSurface
if self.PacManDirection == "UP":
CurrentSurface = pygame.transform.rotate(CurrentSurface, 90)
if self.PacManDirection == "DOWN":
CurrentSurface = pygame.transform.rotate(CurrentSurface, 270)
def PacManLives(self):
pass
Player = Main()
BackgroundSurface = pygame.transform.scale(BackgroundSurface,
(Player.MAZE_WIDTH,
Player.MAZE_HEIGHT))
BackgroundRect = BackgroundSurface.get_rect()
MazeSurface = pygame.Surface((Player.MAZE_WIDTH, Player.MAZE_HEIGHT))
MazeRect = MazeSurface.get_rect(topleft = (Player.MAZE_OFFSET_X,
Player.MAZE_OFFSET_Y))
Player.DrawMaze(MazeSurface)
Player.GhostPosition()
#Player.GhostMovement()
'''
Before the game starts ...
pregame = True
while pregame:
if key button pressed:
pregame = False
run = True
'''
run = True
while run:
SCREEN.fill(BLACK)
for event in pygame.event.get():
if event.type == pygame.QUIT:
run = False
if event.type == pygame.KEYDOWN:
Player.PacManMovement()
Player.PacManTeleport()
Player.ContinuePacManMovement()
MazeSurface.blit(BackgroundSurface, BackgroundRect)
Player.DrawDots()
Player.DrawEnergizer()
Player.DrawGhosts()
Player.GhostTeleport()
Player.EatDots()
Player.EatEnergizer()
Player.ChaseMode()
MazeSurface.blit(CurrentSurface, CurrentRect)
Player.PacManBite()
SCREEN.blit(MazeSurface, MazeRect)
Player.ShowScore()
pygame.display.update()
CLOCK.tick(FPS)
pygame.quit()
An easy algorithm for moving is simply looking at the available exits from this position and choose where to go.
Watching Pacman for a few minutes leads to a few movement rules:
The direction is only changed on exact map-grid boundaries (true for all entities).
Ghosts do not stop
Ghosts do not reverse direction
... unless becoming edible (out of scope for now)
So I implemented this in a simple heuristic:
Unless in a dead-end, do not reverse
Always move forward, but if we can turn, still prefer forward (60% of the time)
To code this, the GhostSprite simply remembers its current direction in self.direction, which is a compass bearing North, East, South, West. North is toward the top of the window (-Y), West to the left (-X).
This makes the Ghost's direction control reduce down to a single algorithm:
By consulting the map, list the available exits
Is the only available direction in reverse?
Yes: turn around
No:
60% of the time continue forward
40% of the time, choose a random direction for what's available
In my implementation the ghosts jump whole grid co-ordinates. In versions with per-pixel movement, the ghost needs only check that it on an exact grid-boundary before bothering to check for direction changes. Something like a self.rect.x % GRID_SIZE == 0 would achieve that quickly.
** Code **
import pygame
import random
# Window size
WINDOW_WIDTH = 420
WINDOW_HEIGHT = 465
GRID_SIZE = WINDOW_HEIGHT // 21
MAP_WIDTH = 19
MAP_HEIGHT = 21
MAP = [ "###################",
"# # #",
"# ## ### # ### ## #",
"# #",
"# ## # ##### # ## #",
"# # # # #",
"#### ### # ### ####",
"#### # # ####",
"#### # ## ## # ####",
"< # # >",
"#### # ##### # ####",
"#### # c # ####",
"#### # ##### # ####",
"# # #",
"# ## ### # ### ## #",
"# # # #",
"## # # ##### # # ##",
"# # # # #",
"# ###### # ###### #",
"# #",
"###################" ]
BLACK = ( 0, 0, 0)
YELLOW = (255, 255, 0)
BLUE = ( 0, 0, 254)
RED = (255, 0, 0)
LIGHTBLUE= (161, 255, 254)
PINK = (255, 192, 203)
ORANGE = (255, 165, 0)
def pixelPosToGridPos( pixel_x, pixel_y ):
""" Map a window-pixel position to a map-grid position """
return ( pixel_x // GRID_SIZE, pixel_y // GRID_SIZE )
def gridPosToPixelPos( grid_x, grid_y ):
""" Map a grid position to a window-position position """
return ( grid_x * GRID_SIZE, grid_y * GRID_SIZE )
def getMapColour( x, y ):
""" Convert map symbols into colours """
symbol = MAP[y][x]
if ( symbol == '#' ):
return BLUE
elif ( symbol == 'c' ):
return YELLOW
elif ( symbol == 'b' ): # "Shadow" / "Blinky"
return RED
elif ( symbol == 'p' ): # "Speedy" / "Pinky"
return PINK
elif ( symbol == 'i' ): # "Bashful" / "Inky"
return LIGHTBLUE
elif ( symbol == 'o' ): # "Pokey" / "Clyde"
return ORANGE
return BLACK
class GhostSprite( pygame.sprite.Sprite ):
""" A pacman-like ghost sprite """
def __init__( self, grid_x, grid_y, colour ):
super().__init__()
self.image = pygame.Surface( ( GRID_SIZE, GRID_SIZE), pygame.SRCALPHA )
self.image.fill( colour )
self.rect = self.image.get_rect()
self.rect.topleft = gridPosToPixelPos( grid_x, grid_y )
self.direction = random.choice( [ 'N', 'S', 'E', 'W' ] )
def moveToGrid( self, grid_x, grid_y ):
""" Allow position to be reset """
self.rect.topleft = gridPosToPixelPos( grid_x, grid_y )
def availableMoves( self ):
""" Consult the map to see where is good to go from here.
We only consider walls, not other NPCs """
map_x, map_y = pixelPosToGridPos( self.rect.x, self.rect.y )
exits = []
# handle wrap-around, where it's possible to go "off grid"
if ( map_x <= 0 or map_x >= MAP_WIDTH-1 ):
exits = [ 'E', 'W' ]
else:
# otherwise consult the map
if ( MAP[ map_y-1 ][ map_x ] != '#' ):
exits.append( 'N' )
if ( MAP[ map_y ][ map_x+1 ] != '#' ):
exits.append( 'E' )
if ( MAP[ map_y+1 ][ map_x ] != '#' ):
exits.append( 'S' )
if ( MAP[ map_y ][ map_x-1 ] != '#' ):
exits.append( 'W' )
return exits
def getOppositeDirection( self ):
""" Return the compass-opposite of our current movement direction """
opposites = { 'N':'S', 'S':'N', 'E':'W', 'W':'E' };
return opposites[ self.direction ]
def moveForward( self ):
""" Move in the current direction. Generally we use the map
to keep us in-bounds, but on the wrap-around we can get
close to the edge of the map, so use special handling for
warping """
# handle wrap-around avenue
map_x, map_y = pixelPosToGridPos( self.rect.x, self.rect.y )
if ( MAP[ map_y ][ map_x ] == '<' ):
self.direction = 'W'
self.rect.x = (MAP_WIDTH-1) * GRID_SIZE
elif ( MAP[ map_y ][ map_x ] == '>' ):
self.direction = 'E'
self.rect.x = 0
# Whichever direction we're moving in, go forward
if ( self.direction == 'N' ):
self.rect.y -= GRID_SIZE
elif ( self.direction == 'E' ):
self.rect.x += GRID_SIZE
elif ( self.direction == 'S' ):
self.rect.y += GRID_SIZE
else: # W
self.rect.x -= GRID_SIZE
def update( self ):
""" Move the ghost, mostly forward, never backwards (unless dead-end)
At an intersection, possibly turn """
exits = self.availableMoves()
# Generally: Keep moving in current direction, never u-turn
opposite = self.getOppositeDirection()
# 60% change of continuing forward at an intersection
if ( self.direction in exits and ( len( exits ) == 1 or random.randrange( 0,100 ) <= 60 ) ):
pass
elif ( self.direction not in exits and len( exits ) == 1 ):
self.direction = exits[0] # maybe u-turn
else: # more than 1 exit
if ( opposite in exits ):
exits.remove( opposite )
self.direction = random.choice( exits )
# Move-it- Move-it
self.moveForward()
###
### MAIN
###
pygame.init()
window = pygame.display.set_mode( ( WINDOW_WIDTH, WINDOW_HEIGHT ), pygame.HWSURFACE )
pygame.display.set_caption("Pac Algorithm")
# Make background image of map
background = pygame.Surface( ( WINDOW_WIDTH, WINDOW_HEIGHT ), pygame.SRCALPHA )
for y in range( MAP_HEIGHT ):
for x in range( MAP_WIDTH ):
rect = pygame.Rect( x * GRID_SIZE, y * GRID_SIZE, GRID_SIZE, GRID_SIZE )
pygame.draw.rect( background, getMapColour( x, y ), rect )
# Make the Ghosts
blinky = GhostSprite( 9, 7, RED )
inky = GhostSprite( 8, 9, LIGHTBLUE )
pinky = GhostSprite( 9, 9, PINK )
pokey = GhostSprite(10, 9, ORANGE )
ghosts = pygame.sprite.Group()
ghosts.add( [ blinky, inky, pinky, pokey ] )
# Ghosts move periodically
next_ghost_movement = pygame.time.get_ticks() + 1000
# Main loop
clock = pygame.time.Clock()
running = True
while running:
time_now = pygame.time.get_ticks()
# Handle user-input
for event in pygame.event.get():
if ( event.type == pygame.QUIT ):
running = False
# Movement keys
keys = pygame.key.get_pressed()
if ( keys[pygame.K_UP] ):
print("up")
elif ( keys[pygame.K_DOWN] ):
print("down")
elif ( keys[pygame.K_LEFT] ):
print("left")
elif ( keys[pygame.K_RIGHT] ):
print("right")
elif ( keys[pygame.K_ESCAPE] ):
# Reset the ghosts home
blinky.moveToGrid( 9, 7 )
inky.moveToGrid( 8, 9 )
pinky.moveToGrid( 9, 9 )
pokey.moveToGrid( 10, 9 )
next_ghost_movement = time_now + 1000
# move the ghosts
if ( time_now > next_ghost_movement ):
ghosts.update()
next_ghost_movement = time_now + 100
# Update the window, but not more than 60fps
window.blit( background, ( 0, 0 ) )
ghosts.draw( window )
pygame.display.flip()
# Clamp FPS
clock.tick(30)
pygame.quit()
Related
I need help figuring out tile collisions for a platformer I'm currently making in Pygame. I have movement, with gravity working, as well as a tile map, but I don't really understand how to get collisions with the sprites working. I did make a list that appends all of the tiles that aren't 0 (so 1 or 2) into a list called tile_collisions (see line 113) but I don't really know what to do with that. Also, you can ignore the commented-out code, that was just a failed attempt. I'm trying to make this as simple as possible, without classes, because those aren't allowed for this assignment.
https://github.com/Night-28/Treble-Quest.git
^ The "main.py" file won't run without all of the pngs so if you do want to run it, you might have to download all of them, sorry!
import pygame as py
from tile_map import map
# Pygame setup
py.init()
clock = py.time.Clock()
# COLOURS
bg_colour = (110, 121, 228)
sky_colour = (190, 220, 255)
start_colour = (225, 225, 225)
screen_width = 1280
screen_height = 720
screen = py.display.set_mode((screen_width, screen_height))
p_sprite = py.image.load("plant_drone.png")
p_rect = p_sprite.get_rect()
p_rect.centery = screen_height - 32
grass_block = py.image.load("grass_block.png")
dirt_block = py.image.load("dirt_block.png")
# def collisions(rect, tiles):
# collider_list = []
# for tile in tiles:
# if rect.colliderect(tile):
# collider_list.append(tile)
# return collider_list
#
# def move(rect, movement, tiles):
# collision_types = {"top": False, "bottom": False, "right": False, "left": False}
#
# rect.x += movement[0]
# collider_list = collisions(rect, tile)
# for tile in collider_list:
# if movement[0] > 0:
# rect.right = tile.left
# collision_types["right"] = True
# elif movement[0] < 0:
# rect.left = tile.right
# collision_types["left"] = True
#
# rect.y += movement[1]
# collider_list = collisions(rect, tile)
# for tile in collider_list:
# if movement[1] > 0:
# rect.bottom = tile.top
# collision_types["bottom"] = True
# elif movement[1] < 0:
# rect.top = tile.bottom
# collision_types["top"] = True
#
# return rect, collision_types
# MAIN MENU
def menu():
py.display.set_caption("Game Menu")
while True:
start()
py.display.update()
clock.tick(60)
# START OPTION (BLINKING TEXT)
def start():
start_font = py.font.Font('Halogen.otf', 50)
bg = py.image.load("GM Treble Quest V2.png")
bg_rect = py.Rect((0, 0), bg.get_size())
screen.blit(bg, bg_rect)
n = 0
while True:
start = start_font.render(("Press Enter To Play"), True, start_colour)
if n % 2 == 0:
screen.blit(start, (450, 625))
clock.tick(50000)
else:
screen.blit(bg, bg_rect)
n += 0.5
py.display.update()
clock.tick(3)
for event in py.event.get():
if event.type == py.QUIT:
exit()
elif event.type == py.KEYDOWN:
if event.key == py.K_RETURN:
play()
# GAME
def play():
py.display.set_caption("Treble Quest")
player_y, player_x = p_rect.bottom, 32
velocity_x, velocity_y = 5, 0
ground = 480
gravity_factor = 0.35
acl_factor = -12
while True:
clock.tick(100)
vertical_acl = gravity_factor
screen.fill(sky_colour)
screen.blit(p_sprite, p_rect)
# TILE MAP
tile_collisions = []
y = 0
for row in map:
x = 0
for tile in row:
if tile == 1:
screen.blit(dirt_block, (x * 32, y * 32))
if tile == 2:
screen.blit(grass_block, (x * 32, y * 32))
if tile != 0:
tile_collisions.append(py.Rect(x * 32, y * 32, 32, 32))
x += 1
y += 1
screen.blit(p_sprite, p_rect)
# player_movement = [0, 0]
# if moving_right == True:
# player_movement[0] += 2
# if moving_left == True:
# player_movement[0] -= 2
# player_movement[1] += player
# MOVEMENT
for event in py.event.get():
if event.type == py.QUIT:
exit()
if event.type == py.KEYDOWN:
if velocity_y == 0 and event.key == py.K_w:
vertical_acl = acl_factor
velocity_y += vertical_acl
player_y += velocity_y
if player_y > ground:
player_y = ground
velocity_y = 0
vertical_acl = 0
p_rect.bottom = round(player_y)
keys = py.key.get_pressed()
player_x += (keys[py.K_d] - keys[py.K_a]) * velocity_x
p_rect.centerx = player_x
py.display.update()
menu()
Your code is almost there.
A simple way to do collisions is to iterate through the bunch of rectangles created when you process the map tiles. Check each rectangle to see if it would intersect the player's position.
When your player needs to move, calculate where the move intends to go (don't actually move the player yet). Then check if the target location will overlap with any of the blocker-tiles. If there is no overlap, then move the player. Otherwise the player stops.
In the example code below, I've implemented a illustrative version of this. While this method is simple, and works (mostly), it suffers from a few issues:
If the velocity is high enough, the player's "next position" may jump right through a blocker tile. This is because the code only tests the destination, not the in-between locations.
Also when a potential collision happens, the player just stops. But at high speeds, the player rectangle may stop a few pixels before the collision tile, rather than against the tile, which would be more what a player would expect.
Really you should test to cover these failures. The second issue is easy to fix by calculating how far the player can move in the desired direction, and only move this lesser amount.
Note that I didn't really understand your movement algorithm. There seems to be a velocity, but no stopping. Given I was just illustrating collisions, I hacked it into some kind of working state that suited what I needed to show.
import pygame as py
#from tile_map import map
map = [ [ 0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0 ],
[ 0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0 ],
[ 0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0 ],
[ 0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0 ],
[ 0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0 ],
[ 0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0 ],
[ 0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0 ],
[ 0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0 ],
[ 0,0,0,0,0,0,0,0,0,1,0,0,0,0,0,0,0,0 ],
[ 0,0,0,0,0,0,0,0,1,2,1,0,0,0,0,0,0,0 ],
[ 0,0,0,0,0,0,0,0,0,1,0,0,0,0,0,0,0,0 ],
[ 0,0,0,0,0,0,0,0,0,2,0,0,0,0,0,0,0,0 ],
[ 0,0,0,0,0,0,0,0,0,1,0,0,0,0,0,0,0,0 ],
[ 0,0,0,0,0,0,0,0,0,2,0,0,0,0,0,0,0,0 ],
[ 0,0,0,0,0,0,0,0,0,1,0,0,0,0,0,0,0,0 ],
[ 2,2,2,2,2,2,2,2,2,2,2,2,2,2,2,2,2,2 ] ]
# Pygame setup
py.init()
clock = py.time.Clock()
# COLOURS
bg_colour = (110, 121, 228)
sky_colour = (190, 220, 255)
start_colour = (225, 225, 225)
screen_width = 1280
screen_height = 720
screen = py.display.set_mode((screen_width, screen_height))
def fakeBitmap( width, height, back_colour, text=None, text_colour=(100,100,100) ):
""" Quick function to replace missing bitmaps """
bitmap = py.Surface( ( width, height ) )
bitmap.fill( back_colour )
if ( text != None and len( text.strip() ) > 0 ):
font = py.font.SysFont( None, 10 )
text_bitmap = font.render( text, True, text_colour, back_colour )
bitmap.blit( text_bitmap, text_bitmap.get_rect(center = bitmap.get_rect().center ) )
return bitmap
#p_sprite = py.image.load("plant_drone.png")
p_sprite = fakeBitmap( 32, 32, ( 128,128,0), "PLAYER" )
p_rect = p_sprite.get_rect()
p_rect.centery = screen_height - 32
#grass_block = py.image.load("grass_block.png")
#dirt_block = py.image.load("dirt_block.png")
grass_block = fakeBitmap( 32, 32, ( 0,200,0 ), "grass_block.png" )
dirt_block = fakeBitmap( 32, 32, ( 102,49, 0 ), "dirt_block.png")
# MAIN MENU
def menu():
py.display.set_caption("Game Menu")
while True:
start()
py.display.update()
clock.tick(60)
# START OPTION (BLINKING TEXT)
def start():
#start_font = py.font.Font('Halogen.otf', 50)
start_font = py.font.SysFont( None, 16 )
#bg = py.image.load("GM Treble Quest V2.png")
bg = fakeBitmap( 1280, 1024, ( 0,0,128 ), "GM Treble Quest V2.png" )
bg_rect = py.Rect((0, 0), bg.get_size())
screen.blit(bg, bg_rect)
n = 0
while True:
start = start_font.render(("Press Enter To Play"), True, start_colour)
if n % 2 == 0:
screen.blit(start, (450, 625))
clock.tick(50000)
else:
screen.blit(bg, bg_rect)
n += 0.5
py.display.update()
clock.tick(3)
for event in py.event.get():
if event.type == py.QUIT:
exit()
elif event.type == py.KEYDOWN:
if event.key == py.K_RETURN:
play()
def playerCanMoveTo( player_next, blockers ):
""" Is a player allowed to move to player_next, or will that mean
colliding with any of the rectangles defined in blockers """
can_move = True
# Simple check, is the destination blocked
for block_rect in blockers:
print( "is Player [%d,%d %d %d] inside Block [%d,%d %d %d]" % ( player_next.x, player_next.y, player_next.width, player_next.height, block_rect.x, block_rect.y, block_rect.width, block_rect.height ) )
if ( block_rect.colliderect( player_next ) ):
can_move = False
break # don't need to check further
return can_move
# GAME
def play():
py.display.set_caption("Treble Quest")
player_y, player_x = p_rect.bottom, 32
velocity_x, velocity_y = 5, 0
ground = 480
gravity_factor = 0.35
acl_factor = -12
# Only need to do this once, moved away from main loop
tile_collisions = []
y = 0
for row in map:
x = 0
for tile in row:
if tile != 0:
tile_collisions.append(py.Rect(x * 32, y * 32, 32, 32))
x += 1
y += 1
while True:
clock.tick(100)
vertical_acl = gravity_factor
screen.fill(sky_colour)
screen.blit(p_sprite, p_rect)
# TILE MAP
y = 0
for row in map:
x = 0
for tile in row:
if tile == 1:
screen.blit(dirt_block, (x * 32, y * 32))
if tile == 2:
screen.blit(grass_block, (x * 32, y * 32))
x += 1
y += 1
screen.blit(p_sprite, p_rect)
# MOVEMENT
for event in py.event.get():
if event.type == py.QUIT:
exit()
elif event.type == py.KEYDOWN:
if velocity_y == 0 and event.key == py.K_w:
vertical_acl = acl_factor
velocity_y += vertical_acl
player_y += velocity_y
if player_y > ground:
player_y = ground
velocity_y = 0
vertical_acl = 0
p_rect.bottom = round(player_y)
keys = py.key.get_pressed()
# Accelerate left/right [A] <-> [D]
if ( keys[py.K_a] ):
velocity_x -= 1
velocity_x = max( -5, velocity_x )
elif ( keys[py.K_d] ):
velocity_x += 1
velocity_x = min( 5, velocity_x )
# Is the player allowed to move?
target_rect = p_rect.copy()
target_rect.centerx += velocity_x
# Check where the player would move to, is allowed
if ( playerCanMoveTo( target_rect, tile_collisions ) ):
player_x += velocity_x
p_rect.centerx = player_x
print( "moving %d" % ( velocity_x ) )
else:
velocity_x = 0
print( "blocked" )
py.display.update()
menu()
I'm not managing to get this math correct, and it's a little bit difficult to explain in words. I have managed to create a isometric grid, which you can select the tiles with the mouse perfectly, and I have managed to implement a camera movement using wasd keys and still get the tiles correctly selected, but there is a slightly bug which I can not figure out where is coming from.
This is what happens, but only sometimes, depend where the camera offset is:
when this happens, it is only on the x axis, and not in every tile.
I'm almost giving up on this cause I can't find the bug, thought of posting here to see if anyone had similar problem.
import time
import pygame
import sys
import math
from os import path
from settings import *
from sprites import *
# ------------------------- SETTINGS ---------------------------- #
# COLORS (r, g, b)
WHITE = (255, 255, 255)
BLACK = (0, 0, 0)
DARKGREY = (40, 40, 40)
LIGHTGREY = (100, 100, 100)
GREEN = (0, 255, 0)
BLUE = (0, 0, 255)
RED = (255, 0, 0)
YELLOW = (255, 255, 0)
# game settings
WIDTH = 1024
HEIGHT = 768
FPS = 60
title = "Isometric-Based game"
BGCOLOUR = DARKGREY
TILE_X = 80
TILE_Y = 40
WORLD_X, WORLD_Y = 14, 10
ORIGIN_X, ORIGIN_Y = 5, 1
# Debug
pygame.init()
font = pygame.font.Font(None, 25)
CAMERA_SPEED = 300
def get_info(info_list):
display_surface = pygame.display.get_surface()
for i, key in enumerate(info_list):
text = font.render(str(key) + " : " + str(info_list[key]), True, (255, 255, 255), (0, 0, 0))
text_rect = text.get_rect()
text_rect.y = 20 * i
display_surface.blit(text, text_rect)
# ------------------------- SPRITES ---------------------------- #
class Camera:
def __init__(self, game, x, y):
self.game = game
self.x, self.y = self.game.to_screen(x, y)
self.vx, self.vy = 0, 0
def update(self):
self.get_keys()
self.x += self.vx * self.game.dt
self.y += self.vy * self.game.dt
def get_keys(self):
self.vx, self.vy = 0, 0
keys = pygame.key.get_pressed()
if keys[pygame.K_w]:
self.vy = -CAMERA_SPEED
if keys[pygame.K_s]:
self.vy = CAMERA_SPEED
if keys[pygame.K_a]:
self.vx = -CAMERA_SPEED
if keys[pygame.K_d]:
self.vx = CAMERA_SPEED
if self.vx != 0 and self.vy != 0:
self.vx *= 1.0
self.vy *= 0.50
class MouseSelection:
def __init__(self, game, image):
self.game = game
self.image = image
def update(self):
# get mouse x and y
self.mouse_x, self.mouse_y = pygame.mouse.get_pos()
# get the mouse offset position inside the tile
self.offset_x, self.offset_y = self.mouse_x % TILE_X, self.mouse_y % TILE_Y
self.offset_x += self.game.scroll_x % TILE_X # Add camera scroll to offset
self.offset_y += self.game.scroll_y % TILE_Y
# get the cell number
self.cell_x, self.cell_y = (self.mouse_x // TILE_X), (self.mouse_y // TILE_Y)
self.cell_x += int((self.game.scroll_x // TILE_X)) # Add camera scroll to cell
self.cell_y += int((self.game.scroll_y // TILE_Y))
# get the selected cell in iso grid
self.selected_x = (self.cell_y - ORIGIN_Y) + (self.cell_x - ORIGIN_X)
self.selected_y = (self.cell_y - ORIGIN_Y) - (self.cell_x - ORIGIN_X)
# height and width of a quarter of a tile, select the corner of the tile to nodge to a direction
h, w = TILE_Y / 2, TILE_X / 2
if self.offset_y < (h / w) * (w - self.offset_x):
self.selected_x -= 1
if self.offset_y > (h / w) * self.offset_x + h:
self.selected_y += 1
if self.offset_y < (h / w) * self.offset_x - h:
self.selected_y -= 1
if self.offset_y > (h / w) * (2 * w - self.offset_x) + h:
self.selected_x += 1
# translate the selected cell to world coordinate
self.selectedWorld_x, self.selectedWorld_y = self.game.to_screen(self.selected_x, self.selected_y)
def draw(self):
# Draw the selected tile with the camera scroll offset
self.game.screen.blit(self.image, (self.selectedWorld_x - self.game.scroll_x,
self.selectedWorld_y - self.game.scroll_y))
class SpriteSheet:
def __init__(self, image):
self.image = image
self.frames = []
def get_image(self):
for row in range(2):
for col in range(4):
if row == 0:
image = pygame.Surface((TILE_Y, TILE_Y / 2)).convert_alpha()
image.blit(self.image, (0, 0), (col * TILE_X / 2, row * TILE_Y / 2, TILE_X, TILE_Y))
image = pygame.transform.scale(image, (TILE_X, TILE_Y))
else:
image = pygame.Surface((TILE_Y, TILE_Y)).convert_alpha()
image.blit(self.image, (0, 0), (col * TILE_X / 2, row * TILE_Y / 2, TILE_X, TILE_Y * 2))
image = pygame.transform.scale(image, (TILE_X, TILE_Y * 2))
image.set_colorkey(WHITE)
self.frames.append(image)
return self.frames
# ------------------------- GAME LOOP ---------------------------- #
class Game:
def __init__(self):
pygame.init()
self.screen = pygame.display.set_mode((WIDTH, HEIGHT))
pygame.display.set_caption(title)
self.clock = pygame.time.Clock()
pygame.key.set_repeat(400, 100)
self.debug = {}
self.sprite_sheet_image = pygame.image.load("isometric_whitebg - Copy.png")
self.index = 1
self.scroll_x, self.scroll_y = 0, 0
def new(self):
# initialize all variables and do all the setup for a new game
self.sprite_sheet = SpriteSheet(self.sprite_sheet_image)
self.tile_selected = self.sprite_sheet.get_image()[0]
self.tiles = self.sprite_sheet.get_image()
self.mouse_selection = MouseSelection(self, self.tile_selected)
self.camera = Camera(self, 1, 1)
def run(self):
# game loop - set self.playing = False to end the game
self.playing = True
while self.playing:
self.dt = self.clock.tick(FPS) / 1000
self.events()
self.update()
self.draw()
def quit(self):
pygame.quit()
sys.exit()
def update(self):
# update portion of the game loop
self.camera.update()
self.mouse_selection.update()
self.mx, self.my = pygame.mouse.get_pos()
# -------------------------------------------------- CAMERA SCROLLING ----------------------------------------#
if self.camera.x - self.scroll_x != WIDTH / 2:
self.scroll_x += (self.camera.x - (self.scroll_x + WIDTH / 2)) / 10
if self.camera.y - self.scroll_y != HEIGHT / 2:
self.scroll_y += (self.camera.y - (self.scroll_y + HEIGHT / 2)) / 10
# -------------------------------------------------- CAMERA SCROLLING ----------------------------------------#
self.debug_info()
def to_screen(self, x, y):
screen_x = (ORIGIN_X * TILE_X) + (x - y) * (TILE_X / 2)
screen_y = (ORIGIN_Y * TILE_Y) + (x + y) * (TILE_Y / 2)
return screen_x, screen_y
def draw_world(self):
for y in range(WORLD_Y):
for x in range(WORLD_X):
vWorld_x, vWorld_y = self.to_screen(x, y)
# Invisible tile
if self.index == 0:
self.screen.blit(self.tiles[1], (vWorld_x, vWorld_y))
# Grass
elif self.index == 1:
self.screen.blit(self.tiles[2], (vWorld_x - self.scroll_x, vWorld_y - self.scroll_y))
def draw(self):
self.screen.fill(BGCOLOUR)
self.draw_world()
self.mouse_selection.draw()
get_info(self.debug)
pygame.display.flip()
def debug_info(self):
self.debug["FPS"] = int(self.clock.get_fps())
self.debug["Cell"] = self.mouse_selection.cell_x, self.mouse_selection.cell_y
self.debug["Selected"] = int(self.mouse_selection.selected_x), int(self.mouse_selection.selected_y)
self.debug["Scroll"] = int(self.scroll_x), int(self.scroll_y)
self.debug["Mouse"] = int(self.mx), int(self.my)
self.debug["Mouse_offset"] = int(self.mouse_selection.offset_x), int(self.mouse_selection.offset_y)
def events(self):
# catch all events here
for event in pygame.event.get():
if event.type == pygame.QUIT:
self.quit()
if event.type == pygame.KEYDOWN:
if event.key == pygame.K_ESCAPE:
self.quit()
if event.type == pygame.MOUSEBUTTONDOWN:
if event.button == 1:
pass
game = Game()
while True:
game.new()
game.run()
Define the corner points of the map:
map_outline = [
pygame.math.Vector2(left_x, left_y),
pygame.math.Vector2(top_x, top_y),
pygame.math.Vector2(right_x, right_y,
pygame.math.Vector2(bottom_x, bottom_y)
]
With this information you can calculate the x and y axis of the map:
origin = map_outline[0]
x_axis = (map_outline[1] - map_outline[0]) / columns
y_axis = (map_outline[3] - map_outline[0]) / rows
You can use the x-axis and the y-axis to calculate a point in the map as a function of the row and column:
def transform(p, mat2x2):
x = p[0] * mat2x2[0][0] + p[1] * mat2x2[1][0]
y = p[0] * mat2x2[0][1] + p[1] * mat2x2[1][1]
return pygame.math.Vector2(x, y)
p_position = transform((column + 0.5, row + 0.5), (x_axis, y_axis)) + origin
If you want to get the row and column depending on the mouse cursor, you need to do the opposite. You need to calculate the inverse 2x2 matrix from the x and y axis. Using the inverse matrix, you can calculate the row and column as a function of a point on the map:
def inverseMat2x2(m):
a, b, c, d = m[0].x, m[0].y, m[1].x, m[1].y
det = 1 / (a*d - b*c)
return [(d*det, -b*det), (-c*det, a*det)]
m_pos = pygame.mouse.get_pos()
m_grid_pos = transform(pygame.math.Vector2(m_pos) - origin, point_to_grid)
m_col, m_row = int(m_grid_pos[0]), int(m_grid_pos[1])
Also see PyGameExamplesAndAnswers - Isometric
Minimal example:
replit.com/#Rabbid76/Pygame-IsometircMap
import pygame
pygame.init()
window = pygame.display.set_mode((500, 300))
clock = pygame.time.Clock()
colors = {'g': (40, 128, 40), 'd': (90, 60, 40)}
tilemap = [
'gdddg',
'dgddd',
'ggddg',
'ggddg',
'ddddg',
'dgggd'
]
columns, rows = len(tilemap[0]), len(tilemap)
isometric_tiles = {}
for key, color in colors.items():
tile_surf = pygame.Surface((50, 50), pygame.SRCALPHA)
tile_surf.fill(color)
tile_surf = pygame.transform.rotate(tile_surf, 45)
isometric_size = tile_surf.get_width()
tile_surf = pygame.transform.scale(tile_surf, (isometric_size, isometric_size//2))
isometric_tiles[key] = tile_surf
tile_size = (isometric_size, isometric_size//2)
def tileRect(column, row, tile_size):
x = (column + row) * tile_size[0] // 2
y = ((columns - column - 1) + row) * tile_size[1] // 2
return pygame.Rect(x, y, *tile_size)
game_map = pygame.Surface(((columns+rows) * isometric_size // 2, (columns+rows) * isometric_size // 4), pygame.SRCALPHA)
for column in range(columns):
for row in range(rows):
tile_surf = isometric_tiles[tilemap[row][column]]
tile_rect = tileRect(column, row, tile_size)
game_map.blit(tile_surf, tile_rect)
map_rect = game_map.get_rect(center = window.get_rect().center)
map_outline = [
pygame.math.Vector2(0, columns * isometric_size / 4),
pygame.math.Vector2(columns * isometric_size / 2, 0),
pygame.math.Vector2((columns+rows) * isometric_size // 2, rows * isometric_size / 4),
pygame.math.Vector2(rows * isometric_size / 2, (columns+rows) * isometric_size // 4)
]
for pt in map_outline:
pt += map_rect.topleft
origin = map_outline[0]
x_axis = (map_outline[1] - map_outline[0]) / columns
y_axis = (map_outline[3] - map_outline[0]) / rows
def inverseMat2x2(m):
a, b, c, d = m[0].x, m[0].y, m[1].x, m[1].y
det = 1 / (a*d - b*c)
return [(d*det, -b*det), (-c*det, a*det)]
point_to_grid = inverseMat2x2((x_axis, y_axis))
def transform(p, mat2x2):
x = p[0] * mat2x2[0][0] + p[1] * mat2x2[1][0]
y = p[0] * mat2x2[0][1] + p[1] * mat2x2[1][1]
return pygame.math.Vector2(x, y)
font = pygame.font.SysFont(None, 30)
textO = font.render("O", True, (255, 255, 255))
textX = font.render("X", True, (255, 0, 0))
textY = font.render("Y", True, (0, 255, 0))
p_col, p_row = 2, 2
run = True
while run:
clock.tick(100)
for event in pygame.event.get():
if event.type == pygame.QUIT:
run = False
if event.type == pygame.KEYDOWN:
if event.key == pygame.K_a and p_col > 0:
p_col -= 1
if event.key == pygame.K_d and p_col < columns-1:
p_col += 1
if event.key == pygame.K_w and p_row > 0:
p_row -= 1
if event.key == pygame.K_s and p_row < rows-1:
p_row += 1
p_position = transform((p_col + 0.5, p_row + 0.5), (x_axis, y_axis)) + origin
m_pos = pygame.mouse.get_pos()
m_grid_pos = transform(pygame.math.Vector2(m_pos) - origin, point_to_grid)
m_col, m_row = int(m_grid_pos[0]), int(m_grid_pos[1])
window.fill((0, 0, 0))
window.blit(game_map, map_rect)
pygame.draw.lines(window, (164, 164, 164), True, map_outline, 3)
pygame.draw.line(window, (255, 0, 0), origin, origin+x_axis, 3)
pygame.draw.line(window, (0, 255, 0), origin, origin+y_axis, 3)
pygame.draw.circle(window, (255, 255, 255), origin, 5)
pygame.draw.circle(window, (255, 0, 0), origin+x_axis, 5)
pygame.draw.circle(window, (0, 255, 0), origin+y_axis, 5)
window.blit(textO, textO.get_rect(topright = origin+(-5, 5)))
window.blit(textX, textX.get_rect(bottomright = origin+x_axis+(-5, -5)))
window.blit(textY, textX.get_rect(topright = origin+y_axis+(-5, 5)))
pygame.draw.ellipse(window, (255, 255, 0), (p_position[0]-16, p_position[1]-8, 32, 16))
if 0 <= m_grid_pos[0] < columns and 0 <= m_grid_pos[1] < rows:
tile_rect = tileRect(m_col, m_row, tile_size).move(map_rect.topleft)
pts = [tile_rect.midleft, tile_rect.midtop, tile_rect.midright, tile_rect.midbottom]
pygame.draw.lines(window, (255, 255, 255), True, pts, 4)
pygame.display.update()
pygame.quit()
exit()
I'm making a game with pygame and pymunk as a physics engine. I'm trying to kill a bullet whenever it hits a player or goes past its lifetime.
When I tried to space.remove(self.shape) and the second bullet hits the player, it gives me an "AssertionError: shape not in space, already removed. I simply changed it to teleport the bullets away, and then learned of the real error.
When I have more than one bullet in the space and a bullet hits the enemy player, all the current bullets teleport away, which means that when I tried to remove one bullet, it called the remove on all the bullets and thats why I had the initial error.
However the problem still remains that one bullet is being treated as every bullet.
Why is something that should be a non-static variable being called as a static variable?
I even tried to use deepcopy to see if that fixed it, but to no avail
This is my chunk of code, apologies since I don't know what is needed to understand it.
The key parts are most likely the Bullet class, the shoot() function in the Player class, and the drawBulletCollision() function
# PyGame template.
# Import modules.
import sys, random, math, time, copy
from typing import List
import pygame
from pygame.locals import *
from pygame import mixer
import pymunk
import pymunk.pygame_util
from pymunk.shapes import Segment
from pymunk.vec2d import Vec2d
pygame.mixer.pre_init(44110, -16, 2, 512)
mixer.init()
# Set up the window.
width, height = 1440, 640
screen = pygame.display.set_mode((width, height))
bg = pygame.image.load("space.png")
def draw_bg():
screen.blit(bg, (0, 0))
#load sounds
#death_fx = pygame.mixer.Sound("")
#death_fx.set_volume(0.25)
shoot_fx = mixer.Sound("shot.wav")
shoot_fx.set_volume(0.25)
#mixer.music.load("video.mp3")
#mixer.music.play()
#time.sleep(2)
#mixer.music.stop()
#gun_mode_fx = pygame.mixer.Sound("")
#gun_mode_fx.set_volume(0.25)
#thrust_mode_fx = pygame.mixer.Sound("")
#thrust_mode_fx.set_volume(0.25)
collision_fx = mixer.Sound("thump.wav")
collision_fx.set_volume(0.25)
ship_group = pygame.sprite.Group()
space = pymunk.Space()
space.gravity = 0, 0
space.damping = 0.6
draw_options = pymunk.pygame_util.DrawOptions(screen)
bulletList = []
playerList = []
environmentList = []
arbiterList = []
b0 = space.static_body
segmentBot = pymunk.Segment(b0, (0,height), (width, height), 4)
segmentTop = pymunk.Segment(b0, (0,0), (width, 0), 4)
segmentLef = pymunk.Segment(b0, (width,0), (width, height), 4)
segmentRit = pymunk.Segment(b0, (0,0), (0, height), 4)
walls = [segmentBot,segmentLef,segmentRit,segmentTop]
for i in walls:
i.elasticity = 1
i.friction = 0.5
i.color = (255,255,255,255)
environmentList.append(i)
class Player(object):
radius = 30
def __init__(self, position, space, color):
self.body = pymunk.Body(mass=5,moment=10)
self.mode = 0 # 0 is gun, 1 is thrust, ? 2 is shield
self.body.position = position
self.shape = pymunk.Circle(self.body, radius = self.radius)
#self.image
#self.shape.friction = 0.9
self.shape.elasticity= 0.2
space.add(self.body,self.shape)
self.angleGun = 0
self.angleThrust = 0
self.health = 100
self.speed = 500
self.gearAngle = 0
self.turningSpeed = 5
self.shape.body.damping = 1000
self.cooldown = 0
self.fireRate = 30
self.shape.collision_type = 1
self.shape.color = color
playerList.append(self)
def force(self,force):
self.shape.body.apply_force_at_local_point(force,(0,0))
def rocketForce(self):
radians = self.angleThrust * math.pi/180
self.shape.body.apply_force_at_local_point((-self.speed * math.cos(radians),-self.speed * math.sin(radians)),(0,0))
def draw(self):
gear = pygame.image.load("gear.png")
gearBox = gear.get_rect(center=self.shape.body.position)
gearRotated = pygame.transform.rotate(gear, self.gearAngle)
#gearRotated.rect.center=self.shape.body.position
x,y = self.shape.body.position
radianGun = self.angleGun * math.pi/180
radianThrust = self.angleThrust * math.pi/180
radiyus = 30 *(100-self.health)/100
screen.blit(gearRotated,gearBox)
self.gearAngle += 1
if radiyus == 30:
radiyus = 32
pygame.draw.circle(screen,self.shape.color,self.shape.body.position,radiyus,0)
pygame.draw.circle(screen,(0,0,0),self.shape.body.position,radiyus,0)
pygame.draw.line(
screen,(0,255,0),
(self.radius * math.cos(radianGun) * 1.5 + x,self.radius * math.sin(radianGun) * 1.5 + y),
(x,y), 5
)
pygame.draw.line(
screen,(200,200,0),
(self.radius * math.cos(radianThrust) * 1.5 + x,self.radius * math.sin(radianThrust) * 1.5 + y),
(x,y), 5
)
#more
def targetAngleGun(self,tAngle):
tempTAngle = tAngle - self.angleGun
tempTAngle = tempTAngle % 360
if(tempTAngle < 180 and not tempTAngle == 0):
self.angleGun -= self.turningSpeed
elif(tempTAngle >= 180 and not tempTAngle == 0):
self.angleGun += self.turningSpeed
self.angleGun = self.angleGun % 360
#print(tAngle, "target Angle")
#print(self.angleGun, "selfangleGun")
#print(tempTAngle, "tempTAngle")
def targetAngleThrust(self,tAngle):
tempTAngle = tAngle - self.angleThrust
tempTAngle = tempTAngle % 360
if(tempTAngle < 180 and not tempTAngle == 0):
self.angleThrust -= self.turningSpeed
elif(tempTAngle >= 180 and not tempTAngle == 0):
self.angleThrust += self.turningSpeed
self.angleThrust = self.angleThrust % 360
#print(tAngle, "target Angle")
#print(self.angleThrust, "selfangleGun")
#print(tempTAngle, "tempTAngle")
def targetAngle(self,tAngle):
if(self.mode == 0):
self.targetAngleGun(tAngle)
elif(self.mode == 1):
self.targetAngleThrust(tAngle)
def shoot(self):
if(self.cooldown == self.fireRate):
x,y = self.shape.body.position
radianGun = self.angleGun * math.pi/180
spawnSpot = (self.radius * math.cos(radianGun) * 1.5 + x,self.radius * math.sin(radianGun)*1.5+y)
self.shape.body.apply_impulse_at_local_point((-20 * math.cos(radianGun),-20 * math.sin(radianGun)),(0,0))
print(spawnSpot)
bT = Bullet(spawnSpot, 5, 50,self.shape.color)
b = copy.deepcopy(bT)
bulletList.append(b)
space.add(b.shape,b.shape.body)
b.getShot(self.angleGun)
self.cooldown = 0
print('pew')
shoot_fx.play()
# HEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEREEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEE
def tick(self):
self.draw()
if(self.cooldown < self.fireRate):
self.cooldown += 1
#for o in playerList:
# c = self.shape.shapes_collide(o.shape)
# if(len(c.points)>0):
# self.damage(c.points[0].distance/10)
for o in bulletList:
c = self.shape.shapes_collide(o.shape)
#print(c)
for o in walls:
c = self.shape.shapes_collide(o)
if(len(c.points)>0):
self.damage(c.points[0].distance * 3)
def damage(self, damage):
self.health -= abs(damage)
if self.health < 0:
self.health = 0
#maybe make it part of the player class
def drawWallCollision(arbiter, space, data):
for c in arbiter.contact_point_set.points:
r = max(3, abs(c.distance * 5))
r = int(r)
p = tuple(map(int, c.point_a))
pygame.draw.circle(data["surface"], pygame.Color("red"), p, r, 0)
print('magnitude', math.sqrt(arbiter.total_impulse[0]**2 + arbiter.total_impulse[1]**2))
#print('position', p)
#print(data)
print("its all arbitrary")
s1, s2 = arbiter.shapes
collision_fx.play()
def drawBulletCollision(arbiter, space, data):
s1, s2 = arbiter.shapes
for c in arbiter.contact_point_set.points:
magnitude = math.sqrt(arbiter.total_impulse[0]**2 + arbiter.total_impulse[1]**2)
for p in playerList:
avr = ((c.point_a[0] + c.point_b[0])/2, (c.point_a[1] + c.point_b[1])/2)
distance = (math.sqrt((avr[0] - p.shape.body.position[0]) **2 + (avr[1] - p.shape.body.position[1]) **2 ))
if(distance < Bullet.explosionRadius + Player.radius):
if not(s1.color == s2.color):
p.damage(magnitude)
for b in bulletList:
avr = ((c.point_a[0] + c.point_b[0])/2, (c.point_a[1] + c.point_b[1])/2)
distance = (math.sqrt((avr[0] - p.shape.body.position[0]) **2 + (avr[1] - p.shape.body.position[1]) **2 ))
if(distance < Bullet.explosionRadius + Player.radius):
if not(s1.color == s2.color):
b.damage(magnitude)
pygame.draw.circle(data["surface"], pygame.Color("red"), tuple(map(int, c.point_a)), 10, 0)
print('magnitude', magnitude)
#print('position', p)
#print(data)
print("its all arbitrary")
def drawArbitraryCollision(arbiter, space, data):
collision_fx.play()
class Ship(pygame.sprite.Sprite):
def __init__(self, x, y):
pygame.sprite.Sprite.__init__(self)
self.image = pygame.image.load("gear.png")
self.rect = self.image.get_rect()
self.rect.center = [x, y]
def rotate(self):
self.image = pygame.transform.rotate(self.image,1)
class Bullet(object):
damage = 2
explosionRadius = 5
def __init__(self, position, size, speed,color):
pts = [(-size, -size), (size, -size), (size, size), (-size, size)]
self.body = copy.deepcopy(pymunk.Body(mass=0.1,moment=1))
self.shape = copy.deepcopy(pymunk.Poly(self.body, pts))
self.shape.body.position = position
self.shape.friction = 0.5
self.shape.elasticity = 1
self.shape.color = color
self.speed = speed
self.size = size
self.shape.collision_type = 2
#space.add(self.body,self.shape)
#bulletList.append(self)
self.lifetime = 0
def getShot(self,angle):
radians = angle * math.pi/180
self.shape.body.apply_impulse_at_local_point((self.speed * math.cos(radians),self.speed * math.sin(radians)),(0,0))
def tick(self):
self.lifetime += 1
if(self.lifetime > 300):
self.shape.body.position = (10000,30)
def damage(self, damage):
self.lifetime = 300
#VELOCITY OF BULLET STARTS WITH VELOCITY OF PLAYER
#MAKE VOLUME OF SOUND DEPEND ON THE IMPULSE FOR THE IMPACTS
#error on purpose so you notice this
#INSTANCES NOT WORKING????
def runPyGame():
# Initialise PyGame.
pygame.init()
# Set up the clock. This will tick every frame and thus maintain a relatively constant framerate. Hopefully.
fps = 60.0
fpsClock = pygame.time.Clock()
running = True
font = pygame.font.SysFont("Arial", 16)
p1 = Player((240,240),space,(132, 66, 245,255))
p2 = Player((1200,400),space,(47, 247, 184,255))
space.add(segmentBot,segmentTop,segmentLef,segmentRit)
# Main game loop.
ch = space.add_collision_handler(1, 0)
ch.data["surface"] = screen
ch.post_solve = drawWallCollision
ch = space.add_collision_handler(1, 2)
ch.data["surface"] = screen
ch.post_solve = drawBulletCollision
ch = space.add_collision_handler(0, 2)
ch.data["surface"] = screen
ch.post_solve = drawArbitraryCollision
dt = 1/fps # dt is the time since last frame.
while True: # Loop forever!
keys = pygame.key.get_pressed()
for event in pygame.event.get():
# We need to handle these events. Initially the only one you'll want to care
# about is the QUIT event, because if you don't handle it, your game will crash
# whenever someone tries to exit.
if event.type == QUIT:
pygame.quit() # Opposite of pygame.init
sys.exit() # Not including this line crashes the script on Windows.
if event.type == KEYDOWN:
if event.key == pygame.K_s:
p1.mode = -(p1.mode - 0.5) + 0.5
print(p1.mode)
if (event.key == pygame.K_k and p1.mode == 0):
p1.shoot()
if event.key == pygame.K_KP_5:
p2.mode = -(p2.mode - 0.5) + 0.5
print(p2.mode)
if (event.key == pygame.K_m and p2.mode == 0):
p2.shoot()
#b = Bullet((200,200),51,51)
if(keys[K_w]):
p1.targetAngle(90)
if(keys[K_q]):
p1.targetAngle(45)
if(keys[K_a]):
p1.targetAngle(0)
if(keys[K_z]):
p1.targetAngle(315)
if(keys[K_x]):
p1.targetAngle(270)
if(keys[K_c]):
p1.targetAngle(225)
if(keys[K_d]):
p1.targetAngle(180)
if(keys[K_e]):
p1.targetAngle(135)
if(keys[K_k] and p1.mode == 1):
p1.rocketForce()
if(keys[K_KP_8]):
p2.targetAngle(90)
if(keys[K_KP_7]):
p2.targetAngle(45)
if(keys[K_KP_4]):
p2.targetAngle(0)
if(keys[K_KP_1]):
p2.targetAngle(315)
if(keys[K_KP_2]):
p2.targetAngle(270)
if(keys[K_KP_3]):
p2.targetAngle(225)
if(keys[K_KP_6]):
p2.targetAngle(180)
if(keys[K_KP_9]):
p2.targetAngle(135)
if(keys[K_m] and p2.mode == 1):
p2.rocketForce()
# Handle other events as you wish.
screen.fill((250, 250, 250)) # Fill the screen with black.
# Redraw screen here.
### Draw stuff
draw_bg()
space.debug_draw(draw_options)
for i in playerList:
i.tick()
screen.blit(
font.render("P1 Health: " + str(p1.health), True, pygame.Color("white")),
(50, 10),
)
screen.blit(
font.render("P2 Health: " + str(p2.health), True, pygame.Color("white")),
(50, 30),
)
for i in bulletList:
i.tick()
ship_group.draw(screen)
# Flip the display so that the things we drew actually show up.
pygame.display.update()
dt = fpsClock.tick(fps)
space.step(0.01)
pygame.display.update()
runPyGame()
I cant point to the exact error since the code is quite long and depends on files I dont have. But here is a general advice for troubleshooting:
Try to give a name to each shape when you create them, and then print it out. Also print out the name of each shape that you add or remove from the space. This should show which shape you are actually removing and will probably make it easy to understand whats wrong.
For example:
...
self.shape = pymunk.Circle(self.body, radius = self.radius)
self.shape.name = "circle 1"
print("Created", self.shape.name)
...
print("Adding", self.shape.name)
space.add(self.body,self.shape)
...
(Note that you need to reset the name of shapes you copy, since otherwise the copy will have the same name.)
i have a problem with this code, i am a new person with programming and been using the book "how to think like a computer scientist 3rd edition" and he did not solve exercise 2 of chapter 17 this given: "he deliberately left a mistake in the code to animate Duke. If you click on one of the checkerboard squares to the right of Duke, he salutes anyway. Why? Find a one-line solution to the error ", I've tried many forms but I have not succeeded, I leave you all the code and the images that I have used
PS: images must have the name: ball.png and duke_spritesheet.png
import pygame
gravity = 0.025
my_clock = pygame.time.Clock()
class QueenSprite:
def __init__(self, img, target_posn):
self.image = img
self.target_posn = target_posn
(x, y) = target_posn
self.posn = (x, 0) # Start ball at top of its column
self.y_velocity = 0 # with zero initial velocity
def update(self):
self.y_velocity += gravity
(x, y) = self.posn
new_y_pos = y + self.y_velocity
(target_x, target_y) = self.target_posn # Unpack the position
dist_to_go = target_y - new_y_pos # How far to our floor?
if dist_to_go < 0: # Are we under floor?
self.y_velocity = -0.65 * self.y_velocity # Bounce
new_y_pos = target_y + dist_to_go # Move back above floor
self.posn = (x, new_y_pos) # Set our new position.
def draw(self, target_surface): # Same as before.
target_surface.blit(self.image, self.posn)
def contains_point(self, pt):
""" Return True if my sprite rectangle contains point pt """
(my_x, my_y) = self.posn
my_width = self.image.get_width()
my_height = self.image.get_height()
(x, y) = pt
return ( x >= my_x and x < my_x + my_width and
y >= my_y and y < my_y + my_height)
def handle_click(self):
self.y_velocity += -2 # Kick it up
class DukeSprite:
def __init__(self, img, target_posn):
self.image = img
self.posn = target_posn
self.anim_frame_count = 0
self.curr_patch_num = 0
def update(self):
if self.anim_frame_count > 0:
self.anim_frame_count = (self.anim_frame_count + 1 ) % 60
self.curr_patch_num = self.anim_frame_count // 6
def draw(self, target_surface):
patch_rect = (self.curr_patch_num * 50, 0,
50, self.image.get_width())
target_surface.blit(self.image, self.posn, patch_rect)
def contains_point(self, pt):
""" Return True if my sprite rectangle contains pt """
(my_x, my_y) = self.posn
my_width = self.image.get_width()
my_height = self.image.get_height()
(x, y) = pt
return ( x >= my_x and x < my_x + my_width and
y >= my_y and y < my_y + my_height)
def handle_click(self):
if self.anim_frame_count == 0:
self.anim_frame_count = 5
def draw_board(the_board):
""" Draw a chess board with queens, as determined by the the_board. """
pygame.init()
colors = [(255,0,0), (0,0,0)] # Set up colors [red, black]
n = len(the_board) # This is an NxN chess board.
surface_sz = 480 # Proposed physical surface size.
sq_sz = surface_sz // n # sq_sz is length of a square.
surface_sz = n * sq_sz # Adjust to exactly fit n squares.
# Create the surface of (width, height), and its window.
surface = pygame.display.set_mode((surface_sz, surface_sz))
ball = pygame.image.load("ball.png")
# Use an extra offset to centre the ball in its square.
# If the square is too small, offset becomes negative,
# but it will still be centered :-)
ball_offset = (sq_sz-ball.get_width()) // 2
all_sprites = [] # Keep a list of all sprites in the game
# Create a sprite object for each queen, and populate our list.
for (col, row) in enumerate(the_board):
a_queen = QueenSprite(ball,
(col*sq_sz+ball_offset, row*sq_sz+ball_offset))
all_sprites.append(a_queen)
# Load the sprite sheet
duke_sprite_sheet = pygame.image.load("duke_spritesheet.png")
# Instantiate two duke instances, put them on the chessboard
duke1 = DukeSprite(duke_sprite_sheet,(sq_sz*2, 0))
duke2 = DukeSprite(duke_sprite_sheet,(sq_sz*5, sq_sz))
# Add them to the list of sprites which our game loop manages
all_sprites.append(duke1)
all_sprites.append(duke2)
while True:
# Look for an event from keyboard, mouse, etc.
ev = pygame.event.poll()
if ev.type == pygame.QUIT:
break;
if ev.type == pygame.KEYDOWN:
key = ev.dict["key"]
if key == 27: # On Escape key ...
break # leave the game loop.
if key == ord("r"):
colors[0] = (255, 0, 0) # Change to red + black.
elif key == ord("g"):
colors[0] = (0, 255, 0) # Change to green + black.
elif key == ord("b"):
colors[0] = (0, 0, 255) # Change to blue + black.
if ev.type == pygame.MOUSEBUTTONDOWN: # Mouse gone down?
posn_of_click = ev.dict["pos"] # Get the coordinates.
for sprite in all_sprites:
if sprite.contains_point(posn_of_click):
sprite.handle_click()
break
for sprite in all_sprites:
sprite.update()
# Draw a fresh background (a blank chess board)
for row in range(n): # Draw each row of the board.
c_indx = row % 2 # Alternate starting color
for col in range(n): # Run through cols drawing squares
the_square = (col*sq_sz, row*sq_sz, sq_sz, sq_sz)
surface.fill(colors[c_indx], the_square)
# Now flip the color index for the next square
c_indx = (c_indx + 1) % 2
# Ask every sprite to draw itself.
for sprite in all_sprites:
sprite.draw(surface)
my_clock.tick(60) # Waste time so that frame rate becomes 60 fps
pygame.display.flip()
pygame.quit()
if __name__ == "__main__":
draw_board([0, 5, 3, 1, 6, 4, 2]) # 7 x 7 to test window size
PS: I think the error is here but it did not succeed
return ( x >= my_x and x + my_width and y >= my_y and y < my_y + my_height)
The issue is caused by the face, that "duke_spritesheet.png" is a sprite sheet. When you define the rectangular region which is covered by the object, then you have to use the width of a single image, rather than the width of the entire sprite sheet:
my_width = self.image.get_width()
my_width = 50
Change this in the method contains_point of the class DukeSprite:
class DukeSprite:
# [...]
def contains_point(self, pt):
""" Return True if my sprite rectangle contains pt """
(my_x, my_y) = self.posn
my_width = 50
my_height = self.image.get_height()
(x, y) = pt
return ( x >= my_x and x < my_x + my_width and
y >= my_y and y < my_y + my_height)
So I want it to count the score every time the snake eats a candy.
I haven't tried much, but I tried to find existing codes and adding them to mine but that just broke the game. I also tried to make my own score board by watching a tutorial, but I don't know where the code should go like at the beginning or end.
import pygame
import random
score = 0
welcome = ("Welcome to our snake game")
print(welcome)
class cube:
height = 20
w = 500
def __init__(movee,start,x=1,y=0,color=(0,0,0)):
movee.pos = start
movee.x = 1
movee.y = 0
movee.color = color
def move(movee, x, y):
movee.x = x
movee.y = y
movee.pos = (movee.pos[0] + movee.x, movee.pos[1] + movee.y)
def draw(movee, surface, eyes=False):
leng = movee.w // movee.height
i = movee.pos[0]
j = movee.pos[1]
pygame.draw.rect(surface, movee.color, (i*leng+1,j*leng+1, leng-2, leng-2))
class snake:
body = []
turns = {}
def __init__(movee, color, pos):
movee.color = color
movee.head = cube(pos)
movee.body.append(movee.head)
def move(movee):
for event in pygame.event.get():
if event.type == pygame.QUIT:
pygame.quit()
keys = pygame.key.get_pressed()
for key in keys:
if keys[pygame.K_LEFT]:
movee.x = -1
movee.y = 0
movee.turns[movee.head.pos[:]] = [movee.x, movee.y]
elif keys[pygame.K_RIGHT]:
movee.x = 1
movee.y = 0
movee.turns[movee.head.pos[:]] = [movee.x, movee.y]
elif keys[pygame.K_UP]:
movee.x = 0
movee.y = -1
movee.turns[movee.head.pos[:]] = [movee.x, movee.y]
elif keys[pygame.K_DOWN]:
movee.x = 0
movee.y = 1
movee.turns[movee.head.pos[:]] = [movee.x, movee.y]
for i, c in enumerate(movee.body):
p = c.pos[:]
if p in movee.turns:
turn = movee.turns[p]
c.move(turn[0],turn[1])
if i == len(movee.body)-1:
movee.turns.pop(p)
else:
if c.x == -1 and c.pos[0] <= 0: c.pos = (c.height-1, c.pos[1])
elif c.x == 1 and c.pos[0] >= c.height-1: c.pos = (0,c.pos[1])
elif c.y == 1 and c.pos[1] >= c.height-1: c.pos = (c.pos[0], 0)
elif c.y == -1 and c.pos[1] <= 0: c.pos = (c.pos[0],c.height-1)
else: c.move(c.x,c.y)
def add(movee):
tail = movee.body[-1]
dx, dy = tail.x, tail.y
if dx == 1 and dy == 0:
movee.body.append(cube((tail.pos[0]-1,tail.pos[1])))
elif dx == -1 and dy == 0:
movee.body.append(cube((tail.pos[0]+1,tail.pos[1])))
elif dx == 0 and dy == 1:
movee.body.append(cube((tail.pos[0],tail.pos[1]-1)))
elif dx == 0 and dy == -1:
movee.body.append(cube((tail.pos[0],tail.pos[1]+1)))
movee.body[-1].x = dx
movee.body[-1].y = dy
def draw(movee, surface):
for i, c in enumerate(movee.body):
if i ==0:
c.draw(surface, True)
else:
c.draw(surface)
def drawingAGrid(w, height, surface):
sizein = w // height
x = 0
y = 0
for l in range(height):
x = x + sizein
y = y + sizein
def redrawGrid(surface):
global height, width, s, snack
surface.fill((255,255,255))
s.draw(surface)
snack.draw(surface)
drawingAGrid(width, height, surface)
pygame.display.update()
def Candy(height, item):
positions = item.body
while True:
x = random.randrange(height)
y = random.randrange(height)
if len(list(filter(lambda z:z.pos == (x,y), positions))) > 0:
continue
else:
break
return (x,y)
def gameloop():
global width, height, s, snack, x_pos, y_pos, reset
width = 500
height = 20
win = pygame.display.set_mode((width, width))
s = snake((255, 0, 0), (10, 10))
snack = cube(Candy(height, s), color=(0, 0, 0))
flag = True
clock = pygame.time.Clock()
x_pos, y_pos = s.body[0].pos
while flag:
pygame.time.delay(50)
clock.tick(7)
s.move()
x, y = s.body[0].pos
if not -1 <= x - x_pos <= 1 or not -1 <= y - y_pos <= 1:
movee.reset((10,10))
x_pos, y_pos = s.body[0].pos
if s.body[0].pos == snack.pos:
s.add()
snack = cube(Candy(height, s), color=(0, 0, 0))
redrawGrid(win)
gameloop()
I just want like a scoreboard in any of the corners counting the score.
Use pygame.freetype to render text. e,g, crated a pygame.freetype.SysFont object:
import pygame.freetype
pygame.init()
font = pygame.freetype.SysFont('Times New Roman', 30)
The score is the number of body parts. Use str to convert a number to a text and .render() to render a text to a pygame.Surface object:
score = len(s.body)
text_surf, text_rect = font.render(str(score), (255, 0, 0), size=30)
Define a margin to the border of the window, calculate the text position (e.g. bottom right) and .blit the text to the window surfrace:
margin = 10
text_pos = (width - text_rect.width - margin, width - text_rect.height - margin)
surface.blit(text_surf, text_pos)
Function redrawGrid:
def redrawGrid(surface):
global height, width, s, snack
surface.fill((255,255,255))
s.draw(surface)
snack.draw(surface)
drawingAGrid(width, height, surface)
score = len(s.body)
text_surf, text_rect = font.render(str(score), (255, 0, 0), size=30)
margin = 10
text_pos = (width - text_rect.width - margin, width - text_rect.height - margin)
surface.blit(text_surf, text_pos)
pygame.display.update()