Python实现我的世界小游戏源代码
程序员文章站
2022-06-16 17:46:19
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...
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:
from __future__ import division import sys import math import random import time from collections import deque from pyglet import image from pyglet.gl import * from pyglet.graphics import texturegroup from pyglet.window import key, mouse ticks_per_sec = 60 # size of sectors used to ease block loading. sector_size = 16 walking_speed = 5 flying_speed = 15 gravity = 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 = 50 player_height = 2 if sys.version_info[0] >= 3: xrange = range def 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, # top x-n,y-n,z-n, x+n,y-n,z-n, x+n,y-n,z+n, x-n,y-n,z+n, # bottom x-n,y-n,z-n, x-n,y-n,z+n, x-n,y+n,z+n, x-n,y+n,z-n, # left x+n,y-n,z+n, x+n,y-n,z-n, x+n,y+n,z-n, x+n,y+n,z+n, # right x-n,y-n,z+n, x+n,y-n,z+n, x+n,y+n,z+n, x-n,y+n,z+n, # front x+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 / n dx = x * m dy = y * m return dx, dy, dx + m, dy, dx + m, dy + m, dx, dy + m def 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 result texture_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 block containing that position. parameters ---------- position : tuple of len 3 returns ------- block_position : tuple of ints of len 3 """ x, y, z = position x, 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 3 returns ------- sector : tuple of len 3 """ x, y, z = normalize(position) x, y, z = x // sector_size, y // sector_size, z // sector_size return (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() calls self.queue = deque() self._initialize() def _initialize(self): """ initialize the world by placing all the blocks. """ n = 80 # 1/2 width and height of world s = 1 # step size y = 0 # initial y height for 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 randomly o = n - 10 for _ in xrange(120): a = random.randint(-o, o) # x position of the hill b = random.randint(-o, o) # z position of the hill c = -1 # base of the hill h = random.randint(1, 6) # height of the hill s = random.randint(4, 8) # 2 * s is the side length of the hill d = 1 # how quickly to taper off the hills t = 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: continue if (x - 0) ** 2 + (z - 0) ** 2 < 5 ** 2: continue self.add_block((x, y, z), t, immediate=false) s -= d # decrement side lenth so hills taper off def hit_test(self, position, vector, max_distance=8): """ line of sight search from current position. if a block is intersected it is returned, along with the block previously in the line of sight. if no block is found, return none, none. parameters ---------- position : tuple of len 3 the (x, y, z) position to check visibility from. vector : tuple of len 3 the line of sight vector. max_distance : int how many blocks away to search for a hit. """ m = 8 x, y, z = position dx, dy, dz = vector previous = none for _ in xrange(max_distance * m): key = normalize((x, y, z)) if key != previous and key in self.world: return key, previous previous = key x, y, z = x + dx / m, y + dy / m, z + dz / m return none, none def exposed(self, position): """ returns false is given `position` is surrounded on all 6 sides by blocks, true otherwise. """ x, y, z = position for dx, dy, dz in faces: if (x + dx, y + dy, z + dz) not in self.world: return true return false def add_block(self, position, texture, immediate=true): """ add a block with the given `texture` and `position` to the world. parameters ---------- position : tuple of len 3 the (x, y, z) position of the block to add. texture : list of len 3 the coordinates of the texture squares. use `tex_coords()` to generate. immediate : bool whether or not to draw the block immediately. """ if position in self.world: self.remove_block(position, immediate) self.world[position] = texture self.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 3 the (x, y, z) position of the block to remove. immediate : bool whether 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 visual state is current. this means hiding blocks that are not exposed and ensuring that all exposed blocks are shown. usually used after a block is added or removed. """ x, y, z = position for dx, dy, dz in faces: key = (x + dx, y + dy, z + dz) if key not in self.world: continue if 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 the block has already been added with add_block() parameters ---------- position : tuple of len 3 the (x, y, z) position of the block to show. immediate : bool whether or not to show the block immediately. """ texture = self.world[position] self.shown[position] = texture if 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 3 the (x, y, z) position of the block to show. texture : list of len 3 the coordinates of the texture squares. use `tex_coords()` to generate. """ x, y, z = position vertex_data = cube_vertices(x, y, z, 0.5) texture_data = list(texture) # create vertex list # fixme maybe `add_indexed()` should be used instead self._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 the block from the world. parameters ---------- position : tuple of len 3 the (x, y, z) position of the block to hide. immediate : bool whether 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 are drawn 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 are removed 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 a contiguous x, y sub-region of world. sectors are used to speed up world rendering. """ before_set = set() after_set = set() pad = 4 for 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: continue if before: x, y, z = before before_set.add((x + dx, y + dy, z + dz)) if after: x, y, z = after after_set.add((x + dx, y + dy, z + dz)) show = after_set - before_set hide = before_set - after_set for 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 allows the game loop to run smoothly. the queue contains calls to _show_block() and _hide_block() so this method should be called if add_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 false the game will ignore the mouse. """ super(window, self).set_exclusive_mouse(exclusive) self.exclusive = exclusive def get_sight_vector(self): """ returns the current line of sight vector indicating the direction the 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)) * m dz = math.sin(math.radians(x - 90)) * m return (dx, dy, dz) def get_motion_vector(self): """ returns the current motion vector indicating the velocity of the player. returns ------- vector : tuple of len 3 tuple containing the velocity in x, y, and z respectively. """ if any(self.strafe): x, y = self.rotation strafe = 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 = 0.0 m = 1 if 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) * m dz = math.sin(x_angle) * m else: dy = 0.0 dx = math.cos(x_angle) dz = math.sin(x_angle) else: dy = 0.0 dx = 0.0 dz = 0.0 return (dx, dy, dz) def update(self, dt): """ this method is scheduled to be called repeatedly by the pyglet clock. parameters ---------- dt : float the 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 = sector m = 8 dt = 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 most of the motion logic lives, along with gravity and collision detection. parameters ---------- dt : float the change in time since the last call. """ # walking speed = flying_speed if self.flying else walking_speed d = 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 # gravity if 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 * gravity self.dy = max(self.dy, -terminal_velocity) dy += self.dy * dt # collisions x, y, z = self.position x, 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 3 the (x, y, z) position to check for collisions at. height : int or float the height of the player. returns ------- position : tuple of len 3 the 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 = 0.25 p = list(position) np = normalize(position) for face in faces: # check all surrounding blocks for i in xrange(3): # check each dimension independently if not face[i]: continue # how much overlap you have with this dimension. d = (p[i] - np[i]) * face[i] if d < pad: continue for dy in xrange(height): # check each height op = list(np) op[1] -= dy op[i] += face[i] if tuple(op) not in self.model.world: continue p[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 = 0 break return tuple(p) def on_mouse_press(self, x, y, button, modifiers): """ called when a mouse button is pressed. see pyglet docs for button amd modifier mappings. parameters ---------- x, y : int the coordinates of the mouse click. always center of the screen if the mouse is captured. button : int number representing mouse button that was clicked. 1 = left button, 4 = right button. modifiers : int number representing any modifying keys that were pressed when the mouse 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 : int the coordinates of the mouse click. always center of the screen if the mouse is captured. dx, dy : float the movement of the mouse. """ if self.exclusive: m = 0.15 x, y = self.rotation x, y = x + dx * m, y + dy * m y = 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 key mappings. parameters ---------- symbol : int number representing the key that was pressed. modifiers : int number representing any modifying keys that were pressed. """ if symbol == key.w: self.strafe[0] -= 1 elif symbol == key.s: self.strafe[0] += 1 elif symbol == key.a: self.strafe[1] -= 1 elif symbol == key.d: self.strafe[1] += 1 elif symbol == key.space: if self.dy == 0: self.dy = jump_speed elif symbol == key.escape: self.set_exclusive_mouse(false) elif symbol == key.tab: self.flying = not self.flying elif 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 key mappings. parameters ---------- symbol : int number representing the key that was pressed. modifiers : int number representing any modifying keys that were pressed. """ if symbol == key.w: self.strafe[0] += 1 elif symbol == key.s: self.strafe[0] -= 1 elif symbol == key.a: self.strafe[1] += 1 elif symbol == key.d: self.strafe[1] -= 1 def on_resize(self, width, height): """ called when the window is resized to a new `width` and `height`. """ # label self.label.y = height - 10 # reticle if self.reticle: self.reticle.delete() x, y = self.width // 2, self.height // 2 n = 10 self.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.rotation glrotatef(x, 0, 1, 0) glrotatef(-y, math.cos(math.radians(x)), 0, math.sin(math.radians(x))) x, y, z = self.position gltranslatef(-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 the crosshairs. """ vector = self.get_sight_vector() block = self.model.hit_test(self.position, vector)[0] if block: x, y, z = block vertex_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.position self.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:
链接: https://pan.baidu.com/s/1gkaherzaenmrxgsu-a4ppg
提取码: rya9
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