本文为大家分享了python实现俄罗斯方块游戏的具体代码,供大家参考,具体内容如下
Github:Tetris
代码:
# -*- coding:utf-8 -*- import pygame, sys, random, copy from pygame.locals import * pygame.init() CubeWidth = 40 CubeHeight = 40 Column = 10 Row = 20 ScreenWidth = CubeWidth * (Column + 5) ScreenHeight = CubeHeight * Row ScreenSize = (ScreenWidth, ScreenHeight) Screen = pygame.display.set_mode(ScreenSize, 0, 32) pygame.display.set_caption("Ly's Tetris") pygame.mixer.music.load('BackgroundMusic.ogg') pygame.mixer.music.play(-1, 0.0) ClickMusic = pygame.mixer.Sound('ClickMusic.wav') ExplodeMusic = pygame.mixer.Sound('Explode.wav') BackgroundImg = pygame.image.load('BackgroundImg.png').convert() PreImg = pygame.image.load('PreImg.png').convert() PStartImg = pygame.image.load('PStartImg.png').convert() ResultPreImg = pygame.image.load('GameResultPreBgImg.png').convert() RestartImg = pygame.image.load('GameResultRestBgImg.png').convert() ScoreHintFont = pygame.font.SysFont('arial', 50) ScoreFont = pygame.font.SysFont('arial', 40) ResultFont = pygame.font.SysFont('arial', 200) Aquamarine = (127, 255, 212) LightGoldenrod = (255, 236, 139) IndianRed = (255, 106, 106) DarkOrchid = (153, 50, 204) RoyalBlue = (72, 118, 255) DarkOrange = (255, 165, 0) Turquoise = (0, 245, 255) IsRect = [] FPSClock = pygame.time.Clock() class I(): def __init__(self): self.Statu = '' self.Color = Aquamarine self.Body = [] x = random.randint(1, 2) if x == 1: self.Statu = 'upright' for i in range(4): InitBody = pygame.Rect(160, i * 40, 40, 40) self.Body.append(InitBody) elif x == 2: self.Statu = 'horizon' for i in range(4): InitBody = pygame.Rect(120 + i * 40, 0, 40, 40) self.Body.append(InitBody) def Fall(self): for rect in self.Body: rect.top += 40 def IsFalled(self): for rect in self.Body: if rect.top == 760: return True if IsRect[int(rect.top / 40) + 1][int(rect.left / 40)]: return True def Move(self, Curkey): CanMoveFlag = True if Curkey == K_UP: self.Rotate() elif Curkey == K_LEFT: for rect in self.Body: if rect.left == 0: CanMoveFlag = not CanMoveFlag break elif IsRect[int(rect.top / 40) + 1][int(rect.left / 40) - 1]: CanMoveFlag = not CanMoveFlag break if CanMoveFlag: for rect in self.Body: rect.left -= 40 elif Curkey == K_RIGHT: for rect in self.Body: if rect.left == 360: CanMoveFlag = not CanMoveFlag break if IsRect[int(rect.top / 40) + 1][int(rect.left / 40) + 1]: CanMoveFlag = not CanMoveFlag break if CanMoveFlag: for rect in self.Body: rect.left += 40 def Rotate(self): if self.Statu == 'upright': TempRotate = copy.deepcopy(self.Body) TempRotate[0].left -= 40 TempRotate[0].top += 40 TempRotate[2].left += 40 TempRotate[2].top -= 40 TempRotate[3].left += 40 * 2 TempRotate[3].top -= 40 * 2 IsRotate = True if TempRotate[0].left < 0: IsRotate = False if TempRotate[3].left > 360: IsRotate = False if IsRotate: for rect in TempRotate: if IsRect[int(rect.top / 40) + 1][int(rect.left / 40)]: IsRotate = False break if IsRotate: self.Body = copy.deepcopy(TempRotate) self.Statu = 'horizon' else: TempRotate = copy.deepcopy(self.Body) TempRotate[0].left += 40 TempRotate[0].top -= 40 TempRotate[2].left -= 40 TempRotate[2].top += 40 TempRotate[3].left -= 40 * 2 TempRotate[3].top += 40 * 2 IsRotate = True if TempRotate[0].top < 0: IsRotate = False if TempRotate[3].top > 760: IsRotate = False if IsRotate: for rect in TempRotate: if IsRect[int(rect.top / 40) + 1][int(rect.left / 40)]: IsRotate = False break if IsRotate: self.Body = copy.deepcopy(TempRotate) self.Statu = 'upright' class O(): def __init__(self): self.Color = LightGoldenrod self.Body = [] for i in range(2): InitBody = pygame.Rect(160, i * 40, 40, 40) self.Body.append(InitBody) for i in range(2): InitBody = pygame.Rect(200, i * 40, 40, 40) self.Body.append(InitBody) def Fall(self): for rect in self.Body: rect.top += 40 def IsFalled(self): for rect in self.Body: if rect.top == 760: return True if IsRect[int(rect.top / 40) + 1][int(rect.left / 40)]: return True def Move(self, Curkey): CanMoveFlag = True if Curkey == K_UP: self.Rotate() elif Curkey == K_LEFT: for rect in self.Body: if rect.left == 0: CanMoveFlag = not CanMoveFlag break elif IsRect[int(rect.top / 40) + 1][int(rect.left / 40) - 1]: CanMoveFlag = not CanMoveFlag break if CanMoveFlag: for rect in self.Body: rect.left -= 40 elif Curkey == K_RIGHT: for rect in self.Body: if rect.left == 360: CanMoveFlag = not CanMoveFlag break if IsRect[int(rect.top / 40) + 1][int(rect.left / 40) + 1]: CanMoveFlag = not CanMoveFlag break if CanMoveFlag: for rect in self.Body: rect.left += 40 def Rotate(self): pass class T(): def __init__(self): self.Statu = '' self.Color = IndianRed self.Body = [] x = random.randint(1, 4) if x == 1: self.Statu = 'up' self.Body.append(pygame.Rect(200, 0, 40, 40)) for i in range(3): self.Body.append(pygame.Rect(160 + i * 40, 40, 40, 40)) elif x == 2: self.Statu = 'left' self.Body.append(pygame.Rect(160, 40, 40, 40)) for i in range(3): self.Body.append(pygame.Rect(200, 80 - i * 40, 40, 40)) elif x == 3: self.Statu = 'down' self.Body.append(pygame.Rect(200, 80, 40, 40)) for i in range(2, -1, -1): self.Body.append(pygame.Rect(160 + i * 40, 40, 40, 40)) elif x == 4: self.Statu = 'right' self.Body.append(pygame.Rect(240, 40, 40, 40)) for i in range(3): self.Body.append(pygame.Rect(200, i * 40, 40, 40)) def Fall(self): for rect in self.Body: rect.top += 40 def IsFalled(self): for rect in self.Body: if rect.top == 760: return True if IsRect[int(rect.top / 40) + 1][int(rect.left / 40)]: return True def Move(self, Curkey): CanMoveFlag = True if Curkey == K_UP: self.Rotate() elif Curkey == K_LEFT: for rect in self.Body: if rect.left == 0: CanMoveFlag = not CanMoveFlag break elif IsRect[int(rect.top / 40) + 1][int(rect.left / 40) - 1]: CanMoveFlag = not CanMoveFlag break if CanMoveFlag: for rect in self.Body: rect.left -= 40 elif Curkey == K_RIGHT: for rect in self.Body: if rect.left == 360: CanMoveFlag = not CanMoveFlag break if IsRect[int(rect.top / 40) + 1][int(rect.left / 40) + 1]: CanMoveFlag = not CanMoveFlag break if CanMoveFlag: for rect in self.Body: rect.left += 40 def Rotate(self): if self.Statu == 'up': TempRotate = copy.deepcopy(self.Body) TempRotate[0].left -= 40 TempRotate[0].top += 40 TempRotate[1].left += 40 TempRotate[1].top += 40 TempRotate[3].left -= 40 TempRotate[3].top -= 40 IsRotate = True if TempRotate[1].top > 760: IsRotate = False if IsRotate: for rect in TempRotate: if IsRect[int(rect.top / 40) + 1][int(rect.left / 40)]: IsRotate = False break if IsRotate: self.Body = copy.deepcopy(TempRotate) self.Statu = 'left' elif self.Statu == 'left': TempRotate = copy.deepcopy(self.Body) TempRotate[0].left += 40 TempRotate[0].top += 40 TempRotate[1].left += 40 TempRotate[1].top -= 40 TempRotate[3].left -= 40 TempRotate[3].top += 40 IsRotate = True if TempRotate[1].left > 360: IsRotate = False if IsRotate: for rect in TempRotate: if IsRect[int(rect.top / 40) + 1][int(rect.left / 40)]: IsRotate = False break if IsRotate: self.Body = copy.deepcopy(TempRotate) self.Statu = 'down' elif self.Statu == 'down': TempRotate = copy.deepcopy(self.Body) TempRotate[0].left += 40 TempRotate[0].top -= 40 TempRotate[1].left -= 40 TempRotate[1].top -= 40 TempRotate[3].left += 40 TempRotate[3].top += 40 IsRotate = True if TempRotate[1].top < 0: IsRotate = False if IsRotate: for rect in TempRotate: if IsRect[int(rect.top / 40) + 1][int(rect.left / 40)]: IsRotate = False break if IsRotate: self.Body = copy.deepcopy(TempRotate) self.Statu = 'right' elif self.Statu == 'right': TempRotate = copy.deepcopy(self.Body) TempRotate[0].left -= 40 TempRotate[0].top -= 40 TempRotate[1].left -= 40 TempRotate[1].top += 40 TempRotate[3].left += 40 TempRotate[3].top -= 40 IsRotate = True if TempRotate[1].top < 0: IsRotate = False if IsRotate: for rect in TempRotate: if IsRect[int(rect.top / 40) + 1][int(rect.left / 40)]: IsRotate = False break if IsRotate: self.Body = copy.deepcopy(TempRotate) self.Statu = 'up' class Z(): def __init__(self): self.Statu = '' self.Color = DarkOrchid self.Body = [] x = random.randint(1, 2) if x == 1: self.Statu = 'horizon' for i in range(2): self.Body.append(pygame.Rect(120 + i * 40, 0, 40, 40)) for i in range(2): self.Body.append(pygame.Rect(160 + i * 40, 40, 40, 40)) elif x == 2: self.Statu = 'upright' for i in range(2): self.Body.append(pygame.Rect(200, i * 40, 40, 40)) for i in range(2): self.Body.append(pygame.Rect(160, 40 + i * 40, 40, 40)) def Fall(self): for rect in self.Body: rect.top += 40 def IsFalled(self): for rect in self.Body: if rect.top == 760: return True if IsRect[int(rect.top / 40) + 1][int(rect.left / 40)]: return True def Move(self, Curkey): CanMoveFlag = True if Curkey == K_UP: self.Rotate() elif Curkey == K_LEFT: for rect in self.Body: if rect.left == 0: CanMoveFlag = not CanMoveFlag break elif IsRect[int(rect.top / 40) + 1][int(rect.left / 40) - 1]: CanMoveFlag = not CanMoveFlag break if CanMoveFlag: for rect in self.Body: rect.left -= 40 elif Curkey == K_RIGHT: for rect in self.Body: if rect.left == 360: CanMoveFlag = not CanMoveFlag break if IsRect[int(rect.top / 40) + 1][int(rect.left / 40) + 1]: CanMoveFlag = not CanMoveFlag break if CanMoveFlag: for rect in self.Body: rect.left += 40 def Rotate(self): if self.Statu == 'horizon': TempRotate = copy.deepcopy(self.Body) TempRotate[0].left += 40 * 2 TempRotate[1].left += 40 TempRotate[1].top += 40 TempRotate[3].left -= 40 TempRotate[3].top += 40 IsRotate = True if TempRotate[3].top > 760: IsRotate = False if IsRotate: for rect in TempRotate: if IsRect[int(rect.top / 40) + 1][int(rect.left / 40)]: IsRotate = False break if IsRotate: self.Body = copy.deepcopy(TempRotate) self.Statu = 'upright' elif self.Statu == 'upright': TempRotate = copy.deepcopy(self.Body) TempRotate[0].left -= 40 * 2 TempRotate[1].left -= 40 TempRotate[1].top -= 40 TempRotate[3].left += 40 TempRotate[3].top -= 40 IsRotate = True if TempRotate[0].left < 0: IsRotate = False if IsRotate: for rect in TempRotate: if IsRect[int(rect.top / 40) + 1][int(rect.left / 40)]: IsRotate = False break if IsRotate: self.Body = copy.deepcopy(TempRotate) self.Statu = 'horizon' class S(): def __init__(self): self.Statu = '' self.Color = DarkOrchid self.Body = [] x = random.randint(1, 2) if x == 1: self.Statu = 'horizon' for i in range(2): self.Body.append(pygame.Rect(200 - i * 40, 0, 40, 40)) for i in range(2): self.Body.append(pygame.Rect(160 - i * 40, 40, 40, 40)) elif x == 2: self.Statu = 'upright' for i in range(2): self.Body.append(pygame.Rect(120, i * 40, 40, 40)) for i in range(2): self.Body.append(pygame.Rect(160, 40 + i * 40, 40, 40)) def Fall(self): for rect in self.Body: rect.top += 40 def IsFalled(self): for rect in self.Body: if rect.top == 760: return True if IsRect[int(rect.top / 40) + 1][int(rect.left / 40)]: return True def Move(self, Curkey): CanMoveFlag = True if Curkey == K_UP: self.Rotate() elif Curkey == K_LEFT: for rect in self.Body: if rect.left == 0: CanMoveFlag = not CanMoveFlag break elif IsRect[int(rect.top / 40) + 1][int(rect.left / 40) - 1]: CanMoveFlag = not CanMoveFlag break if CanMoveFlag: for rect in self.Body: rect.left -= 40 elif Curkey == K_RIGHT: for rect in self.Body: if rect.left == 360: CanMoveFlag = not CanMoveFlag break if IsRect[int(rect.top / 40) + 1][int(rect.left / 40) + 1]: CanMoveFlag = not CanMoveFlag break if CanMoveFlag: for rect in self.Body: rect.left += 40 def Rotate(self): if self.Statu == 'horizon': TempRotate = copy.deepcopy(self.Body) TempRotate[0].left -= 40 * 2 TempRotate[1].left -= 40 TempRotate[1].top += 40 TempRotate[3].left += 40 TempRotate[3].top += 40 IsRotate = True if TempRotate[3].top > 760: IsRotate = False if IsRotate: for rect in TempRotate: if IsRect[int(rect.top / 40) + 1][int(rect.left / 40)]: IsRotate = False break if IsRotate: self.Body = copy.deepcopy(TempRotate) self.Statu = 'upright' elif self.Statu == 'upright': TempRotate = copy.deepcopy(self.Body) TempRotate[0].left += 40 * 2 TempRotate[1].left += 40 TempRotate[1].top -= 40 TempRotate[3].left -= 40 TempRotate[3].top -= 40 IsRotate = True if TempRotate[0].left > 360: IsRotate = False if IsRotate: for rect in TempRotate: if IsRect[int(rect.top / 40) + 1][int(rect.left / 40)]: IsRotate = False break if IsRotate: self.Body = copy.deepcopy(TempRotate) self.Statu = 'horizon' class L(): def __init__(self): self.Statu = '' self.Color = DarkOrange self.Body = [] x = random.randint(1, 4) if x == 1: self.Statu = 'horizonright' self.Body.append(pygame.Rect(120, 0, 40, 40)) for i in range(3): self.Body.append(pygame.Rect(120 + i * 40, 40, 40, 40)) elif x == 2: self.Statu = 'uprightup' self.Body.append(pygame.Rect(120, 80, 40, 40)) for i in range(3): self.Body.append(pygame.Rect(160, 80 - i * 40, 40, 40)) elif x == 3: self.Statu = 'horizonleft' self.Body.append(pygame.Rect(200, 40, 40, 40)) for i in range(3): self.Body.append(pygame.Rect(200 - i * 40, 0, 40, 40)) elif x == 4: self.Statu = 'uprightdown' self.Body.append(pygame.Rect(160, 0, 40, 40)) for i in range(3): self.Body.append(pygame.Rect(120, i * 40, 40, 40)) def Fall(self): for rect in self.Body: rect.top += 40 def IsFalled(self): for rect in self.Body: if rect.top == 760: return True if IsRect[int(rect.top / 40) + 1][int(rect.left / 40)]: return True def Move(self, Curkey): CanMoveFlag = True if Curkey == K_UP: self.Rotate() elif Curkey == K_LEFT: for rect in self.Body: if rect.left == 0: CanMoveFlag = not CanMoveFlag break elif IsRect[int(rect.top / 40) + 1][int(rect.left / 40) - 1]: CanMoveFlag = not CanMoveFlag break if CanMoveFlag: for rect in self.Body: rect.left -= 40 elif Curkey == K_RIGHT: for rect in self.Body: if rect.left == 360: CanMoveFlag = not CanMoveFlag break if IsRect[int(rect.top / 40) + 1][int(rect.left / 40) + 1]: CanMoveFlag = not CanMoveFlag break if CanMoveFlag: for rect in self.Body: rect.left += 40 def Rotate(self): if self.Statu == 'horizonright': TempRotate = copy.deepcopy(self.Body) TempRotate[0].left -= 40 TempRotate[0].top += 40 TempRotate[2].left -= 40 TempRotate[2].top -= 40 TempRotate[3].left -= 40 * 2 TempRotate[3].top -= 40 * 2 IsRotate = True if TempRotate[0].left < 0: IsRotate = False if TempRotate[3].top < 0: IsRotate = False if IsRotate: for rect in TempRotate: if IsRect[int(rect.top / 40) + 1][int(rect.left / 40)]: IsRotate = False break if IsRotate: self.Body = copy.deepcopy(TempRotate) self.Statu = 'uprightup' elif self.Statu == 'uprightup': TempRotate = copy.deepcopy(self.Body) TempRotate[0].left += 40 TempRotate[0].top += 40 TempRotate[2].left -= 40 TempRotate[2].top += 40 TempRotate[3].left -= 40 * 2 TempRotate[3].top += 40 * 2 IsRotate = True if TempRotate[3].left < 0: IsRotate = False if TempRotate[0].top > 760: IsRotate = False if IsRotate: for rect in TempRotate: if IsRect[int(rect.top / 40) + 1][int(rect.left / 40)]: IsRotate = False break if IsRotate: self.Body = copy.deepcopy(TempRotate) self.Statu = 'horizonleft' elif self.Statu == 'horizonleft': TempRotate = copy.deepcopy(self.Body) TempRotate[0].left += 40 TempRotate[0].top -= 40 TempRotate[2].left += 40 TempRotate[2].top += 40 TempRotate[3].left += 40 * 2 TempRotate[3].top += 40 * 2 IsRotate = True if TempRotate[0].left > 360: IsRotate = False if TempRotate[3].top > 760: IsRotate = False if IsRotate: for rect in TempRotate: if IsRect[int(rect.top / 40) + 1][int(rect.left / 40)]: IsRotate = False break if IsRotate: self.Body = copy.deepcopy(TempRotate) self.Statu = 'uprightdown' elif self.Statu == 'uprightdown': TempRotate = copy.deepcopy(self.Body) TempRotate[0].left -= 40 TempRotate[0].top -= 40 TempRotate[2].left += 40 TempRotate[2].top -= 40 TempRotate[3].left += 40 * 2 TempRotate[3].top -= 40 * 2 IsRotate = True if TempRotate[0].top < 0: IsRotate = False if TempRotate[3].left > 360: IsRotate = False if IsRotate: for rect in TempRotate: if IsRect[int(rect.top / 40) + 1][int(rect.left / 40)]: IsRotate = False break if IsRotate: self.Body = copy.deepcopy(TempRotate) self.Statu = 'horizonright' class J(): def __init__(self): self.Statu = '' self.Color = Turquoise self.Body = [] x = random.randint(1, 4) if x == 1: self.Statu = 'horizonleft' self.Body.append(pygame.Rect(200, 0, 40, 40)) for i in range(3): self.Body.append(pygame.Rect(200 - i * 40, 40, 40, 40)) elif x == 2: self.Statu = 'uprightup' self.Body.append(pygame.Rect(240, 80, 40, 40)) for i in range(3): self.Body.append(pygame.Rect(200, 80 - i * 40, 40, 40)) elif x == 3: self.Statu = 'horizonright' self.Body.append(pygame.Rect(120, 40, 40, 40)) for i in range(3): self.Body.append(pygame.Rect(120 + i * 40, 0, 40, 40)) elif x == 4: self.Statu = 'uprightdown' self.Body.append(pygame.Rect(120, 0, 40, 40)) for i in range(3): self.Body.append(pygame.Rect(160, i * 40, 40, 40)) def Fall(self): for rect in self.Body: rect.top += 40 def IsFalled(self): for rect in self.Body: if rect.top == 760: return True if IsRect[int(rect.top / 40) + 1][int(rect.left / 40)]: return True def Move(self, Curkey): CanMoveFlag = True if Curkey == K_UP: self.Rotate() elif Curkey == K_LEFT: for rect in self.Body: if rect.left == 0: CanMoveFlag = not CanMoveFlag break elif IsRect[int(rect.top / 40) + 1][int(rect.left / 40) - 1]: CanMoveFlag = not CanMoveFlag break if CanMoveFlag: for rect in self.Body: rect.left -= 40 elif Curkey == K_RIGHT: for rect in self.Body: if rect.left == 360: CanMoveFlag = not CanMoveFlag break if IsRect[int(rect.top / 40) + 1][int(rect.left / 40) + 1]: CanMoveFlag = not CanMoveFlag break if CanMoveFlag: for rect in self.Body: rect.left += 40 def Rotate(self): if self.Statu == 'horizonleft': TempRotate = copy.deepcopy(self.Body) TempRotate[0].left += 40 TempRotate[0].top += 40 TempRotate[2].left += 40 TempRotate[2].top -= 40 TempRotate[3].left += 40 * 2 TempRotate[3].top -= 40 * 2 IsRotate = True if TempRotate[0].left > 360: IsRotate = False if TempRotate[3].top < 0: IsRotate = False if IsRotate: for rect in TempRotate: if IsRect[int(rect.top / 40) + 1][int(rect.left / 40)]: IsRotate = False break if IsRotate: self.Body = copy.deepcopy(TempRotate) self.Statu = 'uprightup' elif self.Statu == 'uprightup': TempRotate = copy.deepcopy(self.Body) TempRotate[0].left -= 40 TempRotate[0].top += 40 TempRotate[2].left += 40 TempRotate[2].top += 40 TempRotate[3].left += 40 * 2 TempRotate[3].top += 40 * 2 IsRotate = True if TempRotate[3].left > 360: IsRotate = False if TempRotate[0].top > 760: IsRotate = False if IsRotate: for rect in TempRotate: if IsRect[int(rect.top / 40) + 1][int(rect.left / 40)]: IsRotate = False break if IsRotate: self.Body = copy.deepcopy(TempRotate) self.Statu = 'horizonright' elif self.Statu == 'horizonright': TempRotate = copy.deepcopy(self.Body) TempRotate[0].left -= 40 TempRotate[0].top -= 40 TempRotate[2].left -= 40 TempRotate[2].top += 40 TempRotate[3].left -= 40 * 2 TempRotate[3].top += 40 * 2 IsRotate = True if TempRotate[0].left < 0: IsRotate = False if TempRotate[3].top > 760: IsRotate = False if IsRotate: for rect in TempRotate: if IsRect[int(rect.top / 40) + 1][int(rect.left / 40)]: IsRotate = False break if IsRotate: self.Body = copy.deepcopy(TempRotate) self.Statu = 'uprightdown' elif self.Statu == 'uprightdown': TempRotate = copy.deepcopy(self.Body) TempRotate[0].left += 40 TempRotate[0].top -= 40 TempRotate[2].left -= 40 TempRotate[2].top -= 40 TempRotate[3].left -= 40 * 2 TempRotate[3].top -= 40 * 2 IsRotate = True if TempRotate[0].top < 0: IsRotate = False if TempRotate[3].left < 0: IsRotate = False if IsRotate: for rect in TempRotate: if IsRect[int(rect.top / 40) + 1][int(rect.left / 40)]: IsRotate = False break if IsRotate: self.Body = copy.deepcopy(TempRotate) self.Statu = 'horizonleft' def ShapeChoose(): ShapeChoose = random.randint(1, 7) if ShapeChoose == 1: return I() elif ShapeChoose == 2: return O() elif ShapeChoose == 3: return T() elif ShapeChoose == 4: return Z() elif ShapeChoose == 5: return S() elif ShapeChoose == 6: return L() elif ShapeChoose == 7: return J() def GameMain(): global IsRect for row in range(21): TempRowIsRect = [] for column in range(11): TempRowIsRect.append(False) IsRect.append(TempRowIsRect) PreBackgroundImg = PreImg while True: StarFalg = False for event in pygame.event.get(): if event.type == QUIT: pygame.quit() sys.exit() if event.type == KEYDOWN: ClickMusic.play() if event.key == K_SPACE: PreBackgroundImg = PStartImg if event.type == KEYUP: ClickMusic.play() if event.key == K_SPACE: StarFalg = True if StarFalg: break Screen.blit(PreBackgroundImg, (0, 0)) pygame.display.update() falling = ShapeChoose() GameOver = False Score = 0 FallSpeed = 4 while True: # main game loop for event in pygame.event.get(): if event.type == QUIT: pygame.quit() sys.exit() if event.type == KEYDOWN: if event.key == K_DOWN: FallSpeed = 15 else: falling.Move(event.key) if event.type == KEYUP: if event.key == K_DOWN: FallSpeed = 4 Screen.blit(BackgroundImg, (0, 0)) for row in range(20): for column in range(10): if IsRect[row][column]: pygame.draw.rect(Screen, IsRect[row][column][1], IsRect[row][column][0], 0) falling.Fall() for rect in falling.Body: pygame.draw.rect(Screen, falling.Color, rect, 0) if falling.IsFalled(): for rect in falling.Body: Info = [] Info.append(rect) Info.append(falling.Color) IsRect[int(rect.top / 40)][int(rect.left / 40)] = Info falling = ShapeChoose() for IsOver in IsRect[1]: if IsOver: GameOver = True break if GameOver: IsRect = [] return Score for CheckRow in range(19, 0, -1): CheckFlag = True for CheckC in range(10): if IsRect[CheckRow][CheckC]: pass else: CheckFlag = False if CheckFlag: ExplodeMusic.play() Score += 10 for ChangeRow in range(CheckRow, 0, -1): for ChangeC in range(10): if IsRect[ChangeRow - 1][ChangeC]: IsRect[ChangeRow - 1][ChangeC][0].top += 40 IsRect[ChangeRow] = IsRect[ChangeRow - 1] ScoreHintSurface = ScoreHintFont.render('Score:', True, (0, 0, 0)) Screen.blit(ScoreHintSurface, (420, 100)) ScoreSurface = ScoreFont.render(str(Score), True, (0, 0, 0)) Screen.blit(ScoreSurface, (480, 180)) pygame.display.update() FPSClock.tick(FallSpeed) def GameResult(Score): ResultImg = ResultPreImg while True: for event in pygame.event.get(): if event.type == QUIT: pygame.quit() sys.exit() if event.type == KEYDOWN: ClickMusic.play() if event.key == K_SPACE: ResultImg = RestartImg if event.type == KEYUP: ClickMusic.play() if event.key == K_SPACE: return True Screen.blit(ResultImg, (0, 0)) ScoreSurface = ResultFont.render(str(Score), True, (255, 127, 80)) if Score < 10: Screen.blit(ScoreSurface, (250, 260)) elif Score < 100: Screen.blit(ScoreSurface, (210, 260)) elif Score < 1000: Screen.blit(ScoreSurface, (160, 260)) pygame.display.update() if __name__ == '__main__': Flag = True while Flag: Score = GameMain() Flag = GameResult(Score)
运行结果:
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本文向大家介绍Python Pygame实现俄罗斯方块,包括了Python Pygame实现俄罗斯方块的使用技巧和注意事项,需要的朋友参考一下 本文实例为大家分享了Python Pygame实现俄罗斯方块的具体代码,供大家参考,具体内容如下 源码: 效果: 更多俄罗斯方块精彩文章请点击专题:俄罗斯方块游戏集合 进行学习。 以上就是本文的全部内容,希望对大家的学习有所帮助,也希望大家多多支持呐喊教程
本文向大家介绍python 基于pygame实现俄罗斯方块,包括了python 基于pygame实现俄罗斯方块的使用技巧和注意事项,需要的朋友参考一下 一、简单说明 80、90后的小伙伴都玩过“俄罗斯方块”,那种“叱咤风云”场景 偶尔闪现在脑海 真的是太爽了;如果没有来得及玩过的同学,这次可以真正的自己做一个了 本实例用的是Python3(当然了Python3.5 3.6 3.7....都行 )+
本文向大家介绍pyqt5实现俄罗斯方块游戏,包括了pyqt5实现俄罗斯方块游戏的使用技巧和注意事项,需要的朋友参考一下 本章我们要制作一个俄罗斯方块游戏。 Tetris 译注:称呼:方块是由四个小方格组成的 俄罗斯方块游戏是世界上最流行的游戏之一。是由一名叫Alexey Pajitnov的俄罗斯程序员在1985年制作的,从那时起,这个游戏就风靡了各个游戏平台。 俄罗斯方块归类为下落块迷宫游戏。游戏
本章我们要制作一个俄罗斯方块游戏。 Tetris 译注:称呼:方块是由四个小方格组成的 俄罗斯方块游戏是世界上最流行的游戏之一。是由一名叫Alexey Pajitnov的俄罗斯程序员在1985年制作的,从那时起,这个游戏就风靡了各个游戏平台。 俄罗斯方块归类为下落块迷宫游戏。游戏有7个基本形状:S、Z、T、L、反向L、直线、方块,每个形状都由4个方块组成,方块最终都会落到屏幕底部。所以玩家通过控制
本章我们要制作一个俄罗斯方块游戏。 Tetris 译注:称呼:方块是由四个小方格组成的 俄罗斯方块游戏是世界上最流行的游戏之一。是由一名叫 Alexey Pajitnov 的俄罗斯程序员在 1985 年制作的,从那时起,这个游戏就风靡了各个游戏平台。 俄罗斯方块归类为下落块迷宫游戏。游戏有 7 个基本形状:S、Z、T、L、反向 L、直线、方块,每个形状都由 4 个方块组成,方块最终都会落到屏幕底部
本文向大家介绍javascript+css实现俄罗斯方块小游戏,包括了javascript+css实现俄罗斯方块小游戏的使用技巧和注意事项,需要的朋友参考一下 俄罗斯方块,一个很有趣的一个小游戏,此次基于html+css+javaScript实现,包含在一个方块落地后自动生成方块、操控方块的移动以及方块变形等。 部分代码: 游戏截图: 源码可参考:js俄罗斯方块 更多有趣的经典小游戏实现专题,分享