Python我的世界小游戏源代码
2024-04-02 08:44:07
我的世界小游戏使用方法:
移动
前进:W,后退:S,向左:A,向右:D,环顾四周:鼠标,跳起:空格键,切换飞行模式:Tab;
选择建筑材料
砖:1,草:2,沙子:3,删除建筑:鼠标左键单击,创建建筑块:鼠标右键单击
ESC退出程序。
完整程序包请通过文末地址下载,程序运行截图如下:
'''
公众号:Python代码大全
'''
from __future__ import divisionimport sys
import math
import random
import timefrom collections import deque
from pyglet import image
from pyglet.gl import *
from pyglet.graphics import TextureGroup
from pyglet.window import key, mouseTICKS_PER_SEC = 60# Size of sectors used to ease block loading.
SECTOR_SIZE = 16WALKING_SPEED = 5
FLYING_SPEED = 15GRAVITY = 20.0
MAX_JUMP_HEIGHT = 1.0 # About the height of a block.
# To derive the formula for calculating jump speed, first solve
# v_t = v_0 + a * t
# for the time at which you achieve maximum height, where a is the acceleration
# due to gravity and v_t = 0. This gives:
# t = - v_0 / a
# Use t and the desired MAX_JUMP_HEIGHT to solve for v_0 (jump speed) in
# s = s_0 + v_0 * t + (a * t^2) / 2
JUMP_SPEED = math.sqrt(2 * GRAVITY * MAX_JUMP_HEIGHT)
TERMINAL_VELOCITY = 50PLAYER_HEIGHT = 2if sys.version_info[0] >= 3:xrange = rangedef cube_vertices(x, y, z, n):""" Return the vertices of the cube at position x, y, z with size 2*n."""return [x-n,y+n,z-n, x-n,y+n,z+n, x+n,y+n,z+n, x+n,y+n,z-n, # topx-n,y-n,z-n, x+n,y-n,z-n, x+n,y-n,z+n, x-n,y-n,z+n, # bottomx-n,y-n,z-n, x-n,y-n,z+n, x-n,y+n,z+n, x-n,y+n,z-n, # leftx+n,y-n,z+n, x+n,y-n,z-n, x+n,y+n,z-n, x+n,y+n,z+n, # rightx-n,y-n,z+n, x+n,y-n,z+n, x+n,y+n,z+n, x-n,y+n,z+n, # frontx+n,y-n,z-n, x-n,y-n,z-n, x-n,y+n,z-n, x+n,y+n,z-n, # back]def tex_coord(x, y, n=4):""" Return the bounding vertices of the texture square."""m = 1.0 / ndx = x * mdy = y * mreturn dx, dy, dx + m, dy, dx + m, dy + m, dx, dy + mdef tex_coords(top, bottom, side):""" Return a list of the texture squares for the top, bottom and side."""top = tex_coord(*top)bottom = tex_coord(*bottom)side = tex_coord(*side)result = []result.extend(top)result.extend(bottom)result.extend(side * 4)return resultTEXTURE_PATH = 'texture.png'GRASS = tex_coords((1, 0), (0, 1), (0, 0))
SAND = tex_coords((1, 1), (1, 1), (1, 1))
BRICK = tex_coords((2, 0), (2, 0), (2, 0))
STONE = tex_coords((2, 1), (2, 1), (2, 1))FACES = [( 0, 1, 0),( 0,-1, 0),(-1, 0, 0),( 1, 0, 0),( 0, 0, 1),( 0, 0,-1),
]def normalize(position):""" Accepts `position` of arbitrary precision and returns the blockcontaining that position.Parameters----------position : tuple of len 3Returns-------block_position : tuple of ints of len 3"""x, y, z = positionx, y, z = (int(round(x)), int(round(y)), int(round(z)))return (x, y, z)def sectorize(position):""" Returns a tuple representing the sector for the given `position`.Parameters----------position : tuple of len 3Returns-------sector : tuple of len 3"""x, y, z = normalize(position)x, y, z = x // SECTOR_SIZE, y // SECTOR_SIZE, z // SECTOR_SIZEreturn (x, 0, z)class Model(object):def __init__(self):# A Batch is a collection of vertex lists for batched rendering.self.batch = pyglet.graphics.Batch()# A TextureGroup manages an OpenGL texture.self.group = TextureGroup(image.load(TEXTURE_PATH).get_texture())# A mapping from position to the texture of the block at that position.# This defines all the blocks that are currently in the world.self.world = {}# Same mapping as `world` but only contains blocks that are shown.self.shown = {}# Mapping from position to a pyglet `VertextList` for all shown blocks.self._shown = {}# Mapping from sector to a list of positions inside that sector.self.sectors = {}# Simple function queue implementation. The queue is populated with# _show_block() and _hide_block() callsself.queue = deque()self._initialize()def _initialize(self):""" Initialize the world by placing all the blocks."""n = 80 # 1/2 width and height of worlds = 1 # step sizey = 0 # initial y heightfor x in xrange(-n, n + 1, s):for z in xrange(-n, n + 1, s):# create a layer stone an grass everywhere.self.add_block((x, y - 2, z), GRASS, immediate=False)self.add_block((x, y - 3, z), STONE, immediate=False)if x in (-n, n) or z in (-n, n):# create outer walls.for dy in xrange(-2, 3):self.add_block((x, y + dy, z), STONE, immediate=False)# generate the hills randomlyo = n - 10for _ in xrange(120):a = random.randint(-o, o) # x position of the hillb = random.randint(-o, o) # z position of the hillc = -1 # base of the hillh = random.randint(1, 6) # height of the hills = random.randint(4, 8) # 2 * s is the side length of the hilld = 1 # how quickly to taper off the hillst = random.choice([GRASS, SAND, BRICK])for y in xrange(c, c + h):for x in xrange(a - s, a + s + 1):for z in xrange(b - s, b + s + 1):if (x - a) ** 2 + (z - b) ** 2 > (s + 1) ** 2:continueif (x - 0) ** 2 + (z - 0) ** 2 < 5 ** 2:continueself.add_block((x, y, z), t, immediate=False)s -= d # decrement side lenth so hills taper offdef hit_test(self, position, vector, max_distance=8):""" Line of sight search from current position. If a block isintersected it is returned, along with the block previously in the lineof sight. If no block is found, return None, None.Parameters----------position : tuple of len 3The (x, y, z) position to check visibility from.vector : tuple of len 3The line of sight vector.max_distance : intHow many blocks away to search for a hit."""m = 8x, y, z = positiondx, dy, dz = vectorprevious = Nonefor _ in xrange(max_distance * m):key = normalize((x, y, z))if key != previous and key in self.world:return key, previousprevious = keyx, y, z = x + dx / m, y + dy / m, z + dz / mreturn None, Nonedef exposed(self, position):""" Returns False is given `position` is surrounded on all 6 sides byblocks, True otherwise."""x, y, z = positionfor dx, dy, dz in FACES:if (x + dx, y + dy, z + dz) not in self.world:return Truereturn Falsedef add_block(self, position, texture, immediate=True):""" Add a block with the given `texture` and `position` to the world.Parameters----------position : tuple of len 3The (x, y, z) position of the block to add.texture : list of len 3The coordinates of the texture squares. Use `tex_coords()` togenerate.immediate : boolWhether or not to draw the block immediately."""if position in self.world:self.remove_block(position, immediate)self.world[position] = textureself.sectors.setdefault(sectorize(position), []).append(position)if immediate:if self.exposed(position):self.show_block(position)self.check_neighbors(position)def remove_block(self, position, immediate=True):""" Remove the block at the given `position`.Parameters----------position : tuple of len 3The (x, y, z) position of the block to remove.immediate : boolWhether or not to immediately remove block from canvas."""del self.world[position]self.sectors[sectorize(position)].remove(position)if immediate:if position in self.shown:self.hide_block(position)self.check_neighbors(position)def check_neighbors(self, position):""" Check all blocks surrounding `position` and ensure their visualstate is current. This means hiding blocks that are not exposed andensuring that all exposed blocks are shown. Usually used after a blockis added or removed."""x, y, z = positionfor dx, dy, dz in FACES:key = (x + dx, y + dy, z + dz)if key not in self.world:continueif self.exposed(key):if key not in self.shown:self.show_block(key)else:if key in self.shown:self.hide_block(key)def show_block(self, position, immediate=True):""" Show the block at the given `position`. This method assumes theblock has already been added with add_block()Parameters----------position : tuple of len 3The (x, y, z) position of the block to show.immediate : boolWhether or not to show the block immediately."""texture = self.world[position]self.shown[position] = textureif immediate:self._show_block(position, texture)else:self._enqueue(self._show_block, position, texture)def _show_block(self, position, texture):""" Private implementation of the `show_block()` method.Parameters----------position : tuple of len 3The (x, y, z) position of the block to show.texture : list of len 3The coordinates of the texture squares. Use `tex_coords()` togenerate."""x, y, z = positionvertex_data = cube_vertices(x, y, z, 0.5)texture_data = list(texture)# create vertex list# FIXME Maybe `add_indexed()` should be used insteadself._shown[position] = self.batch.add(24, GL_QUADS, self.group,('v3f/static', vertex_data),('t2f/static', texture_data))def hide_block(self, position, immediate=True):""" Hide the block at the given `position`. Hiding does not remove theblock from the world.Parameters----------position : tuple of len 3The (x, y, z) position of the block to hide.immediate : boolWhether or not to immediately remove the block from the canvas."""self.shown.pop(position)if immediate:self._hide_block(position)else:self._enqueue(self._hide_block, position)def _hide_block(self, position):""" Private implementation of the 'hide_block()` method."""self._shown.pop(position).delete()def show_sector(self, sector):""" Ensure all blocks in the given sector that should be shown aredrawn to the canvas."""for position in self.sectors.get(sector, []):if position not in self.shown and self.exposed(position):self.show_block(position, False)def hide_sector(self, sector):""" Ensure all blocks in the given sector that should be hidden areremoved from the canvas."""for position in self.sectors.get(sector, []):if position in self.shown:self.hide_block(position, False)def change_sectors(self, before, after):""" Move from sector `before` to sector `after`. A sector is acontiguous x, y sub-region of world. Sectors are used to speed upworld rendering."""before_set = set()after_set = set()pad = 4for dx in xrange(-pad, pad + 1):for dy in [0]: # xrange(-pad, pad + 1):for dz in xrange(-pad, pad + 1):if dx ** 2 + dy ** 2 + dz ** 2 > (pad + 1) ** 2:continueif before:x, y, z = beforebefore_set.add((x + dx, y + dy, z + dz))if after:x, y, z = afterafter_set.add((x + dx, y + dy, z + dz))show = after_set - before_sethide = before_set - after_setfor sector in show:self.show_sector(sector)for sector in hide:self.hide_sector(sector)def _enqueue(self, func, *args):""" Add `func` to the internal queue."""self.queue.append((func, args))def _dequeue(self):""" Pop the top function from the internal queue and call it."""func, args = self.queue.popleft()func(*args)def process_queue(self):""" Process the entire queue while taking periodic breaks. This allowsthe game loop to run smoothly. The queue contains calls to_show_block() and _hide_block() so this method should be called ifadd_block() or remove_block() was called with immediate=False"""start = time.perf_counter()while self.queue and time.time()- start < 1.0 / TICKS_PER_SEC:self._dequeue()def process_entire_queue(self):""" Process the entire queue with no breaks."""while self.queue:self._dequeue()class Window(pyglet.window.Window):def __init__(self, *args, **kwargs):super(Window, self).__init__(*args, **kwargs)# Whether or not the window exclusively captures the mouse.self.exclusive = False# When flying gravity has no effect and speed is increased.self.flying = False# Strafing is moving lateral to the direction you are facing,# e.g. moving to the left or right while continuing to face forward.## First element is -1 when moving forward, 1 when moving back, and 0# otherwise. The second element is -1 when moving left, 1 when moving# right, and 0 otherwise.self.strafe = [0, 0]# Current (x, y, z) position in the world, specified with floats. Note# that, perhaps unlike in math class, the y-axis is the vertical axis.self.position = (0, 0, 0)# First element is rotation of the player in the x-z plane (ground# plane) measured from the z-axis down. The second is the rotation# angle from the ground plane up. Rotation is in degrees.## The vertical plane rotation ranges from -90 (looking straight down) to# 90 (looking straight up). The horizontal rotation range is unbounded.self.rotation = (0, 0)# Which sector the player is currently in.self.sector = None# The crosshairs at the center of the screen.self.reticle = None# Velocity in the y (upward) direction.self.dy = 0# A list of blocks the player can place. Hit num keys to cycle.self.inventory = [BRICK, GRASS, SAND]# The current block the user can place. Hit num keys to cycle.self.block = self.inventory[0]# Convenience list of num keys.self.num_keys = [key._1, key._2, key._3, key._4, key._5,key._6, key._7, key._8, key._9, key._0]# Instance of the model that handles the world.self.model = Model()# The label that is displayed in the top left of the canvas.self.label = pyglet.text.Label('', font_name='Arial', font_size=18,x=10, y=self.height - 10, anchor_x='left', anchor_y='top',color=(0, 0, 0, 255))# This call schedules the `update()` method to be called# TICKS_PER_SEC. This is the main game event loop.pyglet.clock.schedule_interval(self.update, 1.0 / TICKS_PER_SEC)def set_exclusive_mouse(self, exclusive):""" If `exclusive` is True, the game will capture the mouse, if Falsethe game will ignore the mouse."""super(Window, self).set_exclusive_mouse(exclusive)self.exclusive = exclusivedef get_sight_vector(self):""" Returns the current line of sight vector indicating the directionthe player is looking."""x, y = self.rotation# y ranges from -90 to 90, or -pi/2 to pi/2, so m ranges from 0 to 1 and# is 1 when looking ahead parallel to the ground and 0 when looking# straight up or down.m = math.cos(math.radians(y))# dy ranges from -1 to 1 and is -1 when looking straight down and 1 when# looking straight up.dy = math.sin(math.radians(y))dx = math.cos(math.radians(x - 90)) * mdz = math.sin(math.radians(x - 90)) * mreturn (dx, dy, dz)def get_motion_vector(self):""" Returns the current motion vector indicating the velocity of theplayer.Returns-------vector : tuple of len 3Tuple containing the velocity in x, y, and z respectively."""if any(self.strafe):x, y = self.rotationstrafe = math.degrees(math.atan2(*self.strafe))y_angle = math.radians(y)x_angle = math.radians(x + strafe)if self.flying:m = math.cos(y_angle)dy = math.sin(y_angle)if self.strafe[1]:# Moving left or right.dy = 0.0m = 1if self.strafe[0] > 0:# Moving backwards.dy *= -1# When you are flying up or down, you have less left and right# motion.dx = math.cos(x_angle) * mdz = math.sin(x_angle) * melse:dy = 0.0dx = math.cos(x_angle)dz = math.sin(x_angle)else:dy = 0.0dx = 0.0dz = 0.0return (dx, dy, dz)def update(self, dt):""" This method is scheduled to be called repeatedly by the pygletclock.Parameters----------dt : floatThe change in time since the last call."""self.model.process_queue()sector = sectorize(self.position)if sector != self.sector:self.model.change_sectors(self.sector, sector)if self.sector is None:self.model.process_entire_queue()self.sector = sectorm = 8dt = min(dt, 0.2)for _ in xrange(m):self._update(dt / m)def _update(self, dt):""" Private implementation of the `update()` method. This is where mostof the motion logic lives, along with gravity and collision detection.Parameters----------dt : floatThe change in time since the last call."""# walkingspeed = FLYING_SPEED if self.flying else WALKING_SPEEDd = dt * speed # distance covered this tick.dx, dy, dz = self.get_motion_vector()# New position in space, before accounting for gravity.dx, dy, dz = dx * d, dy * d, dz * d# gravityif not self.flying:# Update your vertical speed: if you are falling, speed up until you# hit terminal velocity; if you are jumping, slow down until you# start falling.self.dy -= dt * GRAVITYself.dy = max(self.dy, -TERMINAL_VELOCITY)dy += self.dy * dt# collisionsx, y, z = self.positionx, y, z = self.collide((x + dx, y + dy, z + dz), PLAYER_HEIGHT)self.position = (x, y, z)def collide(self, position, height):""" Checks to see if the player at the given `position` and `height`is colliding with any blocks in the world.Parameters----------position : tuple of len 3The (x, y, z) position to check for collisions at.height : int or floatThe height of the player.Returns-------position : tuple of len 3The new position of the player taking into account collisions."""# How much overlap with a dimension of a surrounding block you need to# have to count as a collision. If 0, touching terrain at all counts as# a collision. If .49, you sink into the ground, as if walking through# tall grass. If >= .5, you'll fall through the ground.pad = 0.25p = list(position)np = normalize(position)for face in FACES: # check all surrounding blocksfor i in xrange(3): # check each dimension independentlyif not face[i]:continue# How much overlap you have with this dimension.d = (p[i] - np[i]) * face[i]if d < pad:continuefor dy in xrange(height): # check each heightop = list(np)op[1] -= dyop[i] += face[i]if tuple(op) not in self.model.world:continuep[i] -= (d - pad) * face[i]if face == (0, -1, 0) or face == (0, 1, 0):# You are colliding with the ground or ceiling, so stop# falling / rising.self.dy = 0breakreturn tuple(p)def on_mouse_press(self, x, y, button, modifiers):""" Called when a mouse button is pressed. See pyglet docs for buttonamd modifier mappings.Parameters----------x, y : intThe coordinates of the mouse click. Always center of the screen ifthe mouse is captured.button : intNumber representing mouse button that was clicked. 1 = left button,4 = right button.modifiers : intNumber representing any modifying keys that were pressed when themouse button was clicked."""if self.exclusive:vector = self.get_sight_vector()block, previous = self.model.hit_test(self.position, vector)if (button == mouse.RIGHT) or \((button == mouse.LEFT) and (modifiers & key.MOD_CTRL)):# ON OSX, control + left click = right click.if previous:self.model.add_block(previous, self.block)elif button == pyglet.window.mouse.LEFT and block:texture = self.model.world[block]if texture != STONE:self.model.remove_block(block)else:self.set_exclusive_mouse(True)def on_mouse_motion(self, x, y, dx, dy):""" Called when the player moves the mouse.Parameters----------x, y : intThe coordinates of the mouse click. Always center of the screen ifthe mouse is captured.dx, dy : floatThe movement of the mouse."""if self.exclusive:m = 0.15x, y = self.rotationx, y = x + dx * m, y + dy * my = max(-90, min(90, y))self.rotation = (x, y)def on_key_press(self, symbol, modifiers):""" Called when the player presses a key. See pyglet docs for keymappings.Parameters----------symbol : intNumber representing the key that was pressed.modifiers : intNumber representing any modifying keys that were pressed."""if symbol == key.W:self.strafe[0] -= 1elif symbol == key.S:self.strafe[0] += 1elif symbol == key.A:self.strafe[1] -= 1elif symbol == key.D:self.strafe[1] += 1elif symbol == key.SPACE:if self.dy == 0:self.dy = JUMP_SPEEDelif symbol == key.ESCAPE:self.set_exclusive_mouse(False)elif symbol == key.TAB:self.flying = not self.flyingelif symbol in self.num_keys:index = (symbol - self.num_keys[0]) % len(self.inventory)self.block = self.inventory[index]def on_key_release(self, symbol, modifiers):""" Called when the player releases a key. See pyglet docs for keymappings.Parameters----------symbol : intNumber representing the key that was pressed.modifiers : intNumber representing any modifying keys that were pressed."""if symbol == key.W:self.strafe[0] += 1elif symbol == key.S:self.strafe[0] -= 1elif symbol == key.A:self.strafe[1] += 1elif symbol == key.D:self.strafe[1] -= 1def on_resize(self, width, height):""" Called when the window is resized to a new `width` and `height`."""# labelself.label.y = height - 10# reticleif self.reticle:self.reticle.delete()x, y = self.width // 2, self.height // 2n = 10self.reticle = pyglet.graphics.vertex_list(4,('v2i', (x - n, y, x + n, y, x, y - n, x, y + n)))def set_2d(self):""" Configure OpenGL to draw in 2d."""width, height = self.get_size()glDisable(GL_DEPTH_TEST)viewport = self.get_viewport_size()glViewport(0, 0, max(1, viewport[0]), max(1, viewport[1]))glMatrixMode(GL_PROJECTION)glLoadIdentity()glOrtho(0, max(1, width), 0, max(1, height), -1, 1)glMatrixMode(GL_MODELVIEW)glLoadIdentity()def set_3d(self):""" Configure OpenGL to draw in 3d."""width, height = self.get_size()glEnable(GL_DEPTH_TEST)viewport = self.get_viewport_size()glViewport(0, 0, max(1, viewport[0]), max(1, viewport[1]))glMatrixMode(GL_PROJECTION)glLoadIdentity()gluPerspective(65.0, width / float(height), 0.1, 60.0)glMatrixMode(GL_MODELVIEW)glLoadIdentity()x, y = self.rotationglRotatef(x, 0, 1, 0)glRotatef(-y, math.cos(math.radians(x)), 0, math.sin(math.radians(x)))x, y, z = self.positionglTranslatef(-x, -y, -z)def on_draw(self):""" Called by pyglet to draw the canvas."""self.clear()self.set_3d()glColor3d(1, 1, 1)self.model.batch.draw()self.draw_focused_block()self.set_2d()self.draw_label()self.draw_reticle()def draw_focused_block(self):""" Draw black edges around the block that is currently under thecrosshairs."""vector = self.get_sight_vector()block = self.model.hit_test(self.position, vector)[0]if block:x, y, z = blockvertex_data = cube_vertices(x, y, z, 0.51)glColor3d(0, 0, 0)glPolygonMode(GL_FRONT_AND_BACK, GL_LINE)pyglet.graphics.draw(24, GL_QUADS, ('v3f/static', vertex_data))glPolygonMode(GL_FRONT_AND_BACK, GL_FILL)def draw_label(self):""" Draw the label in the top left of the screen."""x, y, z = self.positionself.label.text = '%02d (%.2f, %.2f, %.2f) %d / %d' % (pyglet.clock.get_fps(), x, y, z,len(self.model._shown), len(self.model.world))self.label.draw()def draw_reticle(self):""" Draw the crosshairs in the center of the screen."""glColor3d(0, 0, 0)self.reticle.draw(GL_LINES)def setup_fog():""" Configure the OpenGL fog properties."""# Enable fog. Fog "blends a fog color with each rasterized pixel fragment's# post-texturing color."glEnable(GL_FOG)# Set the fog color.glFogfv(GL_FOG_COLOR, (GLfloat * 4)(0.5, 0.69, 1.0, 1))# Say we have no preference between rendering speed and quality.glHint(GL_FOG_HINT, GL_DONT_CARE)# Specify the equation used to compute the blending factor.glFogi(GL_FOG_MODE, GL_LINEAR)# How close and far away fog starts and ends. The closer the start and end,# the denser the fog in the fog range.glFogf(GL_FOG_START, 20.0)glFogf(GL_FOG_END, 60.0)def setup():""" Basic OpenGL configuration."""# Set the color of "clear", i.e. the sky, in rgba.glClearColor(0.5, 0.69, 1.0, 1)# Enable culling (not rendering) of back-facing facets -- facets that aren't# visible to you.glEnable(GL_CULL_FACE)# Set the texture minification/magnification function to GL_NEAREST (nearest# in Manhattan distance) to the specified texture coordinates. GL_NEAREST# "is generally faster than GL_LINEAR, but it can produce textured 图片# with sharper edges because the transition between texture elements is not# as smooth."glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_NEAREST)glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MAG_FILTER, GL_NEAREST)setup_fog()def main():window = Window(width=1800, height=1600, caption='Pyglet', resizable=True)# Hide the mouse cursor and prevent the mouse from leaving the window.window.set_exclusive_mouse(True)setup()pyglet.app.run()if __name__ == '__main__':main()我的世界小游戏python源代码包下载地址:,Python我的世界小游戏源代码
更多Python源代码,请微信关注:Python代码大全,
Python我的世界小游戏源代码相关推荐
- Python版跳跳方块小游戏源代码,跳跳益智游戏代码
Python版跳跳方块小游戏源代码,跳跳益智游戏代码,通过方向键的左右键来控制方块向左上还右上跳跃,按R键重要开始游戏.相当有难度,快来挑战你自己吧 jump_square.py # import o ...
- Python制作的赛车小游戏源代码,逆行飙车
python制作的赛车小游戏,逆行飙车,通过键盘方向键控制 程序运行截图: 源代码 import pygame, sys, time, random# pygame 初始化 pygame.init() ...
- Python接弹珠小游戏源代码
接弹珠游戏,弹珠碰到上方及左右两侧的墙壁进行反弹,反弹,可以理解成弹珠的坐标值变成相反数.当弹珠的圆心坐标值到达上方墙壁时,只需要让坐标变成负数,弹珠就可以向相反的方向移动了. import pyga ...
- python双手打字_Python打字练习小游戏源代码
Python打字练习小游戏源代码 Python代码狂人 Python代码大全 Python打字练习小游戏源程序,随机产生一串字符,可对打字练习的正确率和时间进行统计,运行截图如下: from tkin ...
- 【源代码】Python制作的赛车小游戏,逆行飙车
python制作的赛车小游戏,逆行飙车,通过键盘方向键控制 程序运行截图 源代码 import pygame, sys, time, random# pygame 初始化 pygame.init() ...
- Python版基于pygame的玛丽快跑小游戏源代码,玛丽冒险小游戏代码,支持双人模式
基于pygame的玛丽快跑小游戏源代码,玛丽冒险小游戏代码,支持双人模式 按空格进入单人模式,按't'进入双人模式,双人模式下玛丽1采用空格键上跳,玛丽2采用方向上键上跳. 完整代码下载地址:Pyth ...
- Python版见缝插针小游戏源代码,球球旋转大作战源程序
见缝插针游戏是一款非常考验玩家手眼协调能力的休闲益智虐心虐脑小游戏,玩法很简单,但要过关却很有挑战性哟! 主要是将一系列的小球,插入到旋转的摩天轮转盘当中,插入过程中不能碰到旋转的摩天轮上的其他小球, ...
- Python版消灭病毒、消灭新冠小游戏源代码
Python版消灭病毒.消灭新冠小游戏源代码,上下方向键控制战斗少女,如果被病毒袭击将会Game Over,按空格键发射火球烧死病毒获得积分. 开始界面 游戏界面 核心代码: game.py # Py ...
- 基于Python pygame简易版斗兽棋小游戏源代码
基于Python pygame简易版斗兽棋小游戏源代码 游戏规则如下: 胜利条件: 1.吃掉对方全部棋子 2.走入对方兽穴(不可进入自己洞穴) 吃法: 1.象>狮>虎>豹>狼& ...
最新文章
- 《强化学习周刊》第7期:强化学习应用之游戏
- WIF - claims-based identity
- C语言实现TEA系列加解密算法
- 工业互联网解决方案创新应用报告(2020)
- 解读文献里的那些图——流式细胞术
- 创建型模式之工厂方法模式
- Java 多线程详解(一)------概念的引入
- 编辑器安卓手机版_手机上最专业的视频编辑器,内购版!
- origin视频教程
- java面向对象数组实现家庭收支记账软件_golang实战--家庭收支记账软件(面向过程)...
- 当天使爱上吸血鬼,上帝开始哭泣
- XP的故障恢复控制台
- 文件上传案例(java)
- 青藤 #10115 栈练习1
- 整理文件夹保存同一目录,并统一重命名文件夹名
- IEEE802.11信道PDP与频谱分布
- javascript世界上最被误解的语言
- A Double-Stage Kalman Filter for Orientation Tracking With An Integrated Processor in 9-D IMU
- WML语言基础(WAP建站)二
- Linux中的软件管理(一)配置本地yum源及yum命令详解