python PyGame五子棋
Lucifer三思而后行 人气:0前言
PyGame 是一个专门设计来进行游戏开发设计的 Python 模块,允许实时电子游戏研发而无需被低级语言(如机器语言和汇编语言)束缚,使用起来非常的简单,非常适合新手拿来玩耍,本教程源码均基于 Python 3.x 版本。
五子棋小游戏
1、简介
五子棋是我们小时候经常玩的两人对弈策略小游戏,规则简单:
1、对局双方各执一色棋子,常为黑白两色;2、空棋盘开局;3、黑先、白后,交替下子,每次只能下一子;4、棋子下在棋盘的空白点上,棋子下定后,不得向其它点移动,不得从棋盘上拿掉或拿起另落别处;5、黑方的第一枚棋子可下在棋盘任意交叉点上;6、轮流下子是双方的权利,但允许任何一方放弃下子权,先形成5子连线者获胜;
五子棋容易上手,规则简单,老少皆宜,而且趣味横生,引人入胜。它不仅能增强思维能力,提高智力,而且富含哲理,有助于修身养性。
2、环境准备
本次教程需要提前安装好 Python 3.x 环境以及 PyGame 模块,Python 环境建议安装 Anaconda 以及 Jupyter,对于新手比较友好!
pip install jupyter pip install pygame
安装好 PyGame 模块之后,咱们就可以正式开写了!
3、初始化环境
首先需要引入以下模块:
import sys import random import pygame from pygame.locals import * import pygame.gfxdraw from collections import namedtuple
接着我们初始化棋盘的一些变量,便于下面写代码:
Chessman = namedtuple('Chessman', 'Name Value Color') Point = namedtuple('Point', 'X Y') BLACK_CHESSMAN = Chessman('黑子', 1, (45, 45, 45)) WHITE_CHESSMAN = Chessman('白子', 2, (219, 219, 219)) offset = [(1, 0), (0, 1), (1, 1), (1, -1)] SIZE = 30 # 棋盘每个点时间的间隔 Line_Points = 19 # 棋盘每行/每列点数 Outer_Width = 20 # 棋盘外宽度 Border_Width = 4 # 边框宽度 Inside_Width = 4 # 边框跟实际的棋盘之间的间隔 Border_Length = SIZE * (Line_Points - 1) + Inside_Width * 2 + Border_Width # 边框线的长度 Start_X = Start_Y = Outer_Width + int(Border_Width / 2) + Inside_Width # 网格线起点(左上角)坐标 SCREEN_HEIGHT = SIZE * (Line_Points - 1) + Outer_Width * 2 + Border_Width + Inside_Width * 2 # 游戏屏幕的高 SCREEN_WIDTH = SCREEN_HEIGHT + 200 # 游戏屏幕的宽 Stone_Radius = SIZE // 2 - 3 # 棋子半径 Stone_Radius2 = SIZE // 2 + 3 Checkerboard_Color = (0xE3, 0x92, 0x65) # 棋盘颜色 BLACK_COLOR = (0, 0, 0) WHITE_COLOR = (255, 255, 255) RED_COLOR = (200, 30, 30) BLUE_COLOR = (30, 30, 200) RIGHT_INFO_POS_X = SCREEN_HEIGHT + Stone_Radius2 * 2 + 10
4、棋盘
通过上述变量画出棋盘,主要源码如下:
# 画棋盘 def _draw_checkerboard(screen): # 填充棋盘背景色 screen.fill(Checkerboard_Color) # 画棋盘网格线外的边框 pygame.draw.rect(screen, BLACK_COLOR, (Outer_Width, Outer_Width, Border_Length, Border_Length), Border_Width) # 画网格线 for i in range(Line_Points): pygame.draw.line(screen, BLACK_COLOR, (Start_Y, Start_Y + SIZE * i), (Start_Y + SIZE * (Line_Points - 1), Start_Y + SIZE * i), 1) for j in range(Line_Points): pygame.draw.line(screen, BLACK_COLOR, (Start_X + SIZE * j, Start_X), (Start_X + SIZE * j, Start_X + SIZE * (Line_Points - 1)), 1) # 画星位和天元 for i in (3, 9, 15): for j in (3, 9, 15): if i == j == 9: radius = 5 else: radius = 3 # pygame.draw.circle(screen, BLACK, (Start_X + SIZE * i, Start_Y + SIZE * j), radius) pygame.gfxdraw.aacircle(screen, Start_X + SIZE * i, Start_Y + SIZE * j, radius, BLACK_COLOR) pygame.gfxdraw.filled_circle(screen, Start_X + SIZE * i, Start_Y + SIZE * j, radius, BLACK_COLOR)
5、黑白棋子
有了棋盘当然少不了黑白棋子,比较简单:
# 画棋子 def _draw_chessman(screen, point, stone_color): # pygame.draw.circle(screen, stone_color, (Start_X + SIZE * point.X, Start_Y + SIZE * point.Y), Stone_Radius) pygame.gfxdraw.aacircle(screen, Start_X + SIZE * point.X, Start_Y + SIZE * point.Y, Stone_Radius, stone_color) pygame.gfxdraw.filled_circle(screen, Start_X + SIZE * point.X, Start_Y + SIZE * point.Y, Stone_Radius, stone_color)
6、对局信息
每一局游戏不可缺少的就是双方玩家的对局信息,主要展示双方的黑白执子以及战况,关键源码如下:
# 画左侧信息显示 def _draw_left_info(screen, font, cur_runner, black_win_count, white_win_count): _draw_chessman_pos(screen, (SCREEN_HEIGHT + Stone_Radius2, Start_X + Stone_Radius2), BLACK_CHESSMAN.Color) _draw_chessman_pos(screen, (SCREEN_HEIGHT + Stone_Radius2, Start_X + Stone_Radius2 * 4), WHITE_CHESSMAN.Color) print_text(screen, font, RIGHT_INFO_POS_X, Start_X + 3, '玩家', BLUE_COLOR) print_text(screen, font, RIGHT_INFO_POS_X, Start_X + Stone_Radius2 * 3 + 3, '电脑', BLUE_COLOR) print_text(screen, font, SCREEN_HEIGHT, SCREEN_HEIGHT - Stone_Radius2 * 8, '战况:', BLUE_COLOR) _draw_chessman_pos(screen, (SCREEN_HEIGHT + Stone_Radius2, SCREEN_HEIGHT - int(Stone_Radius2 * 4.5)), BLACK_CHESSMAN.Color) _draw_chessman_pos(screen, (SCREEN_HEIGHT + Stone_Radius2, SCREEN_HEIGHT - Stone_Radius2 * 2), WHITE_CHESSMAN.Color) print_text(screen, font, RIGHT_INFO_POS_X, SCREEN_HEIGHT - int(Stone_Radius2 * 5.5) + 3, f'{black_win_count} 胜', BLUE_COLOR) print_text(screen, font, RIGHT_INFO_POS_X, SCREEN_HEIGHT - Stone_Radius2 * 3 + 3, f'{white_win_count} 胜', BLUE_COLOR) def _draw_chessman_pos(screen, pos, stone_color): pygame.gfxdraw.aacircle(screen, pos[0], pos[1], Stone_Radius2, stone_color) pygame.gfxdraw.filled_circle(screen, pos[0], pos[1], Stone_Radius2, stone_color)
画出来的整体效果如下:
至此,整个棋盘的布局就完成了!
7、AI
由于咱们的小游戏不可以联机,因此大部分时间应该都是人机对下,这样就需要引入 AI 人机,让电脑作为对手陪我们下棋,主要源码如下:
class AI: def __init__(self, line_points, chessman): self._line_points = line_points self._my = chessman self._opponent = BLACK_CHESSMAN if chessman == WHITE_CHESSMAN else WHITE_CHESSMAN self._checkerboard = [[0] * line_points for _ in range(line_points)] def get_opponent_drop(self, point): self._checkerboard[point.Y][point.X] = self._opponent.Value def AI_drop(self): point = None score = 0 for i in range(self._line_points): for j in range(self._line_points): if self._checkerboard[j][i] == 0: _score = self._get_point_score(Point(i, j)) if _score > score: score = _score point = Point(i, j) elif _score == score and _score > 0: r = random.randint(0, 100) if r % 2 == 0: point = Point(i, j) self._checkerboard[point.Y][point.X] = self._my.Value return point def _get_point_score(self, point): score = 0 for os in offset: score += self._get_direction_score(point, os[0], os[1]) return score def _get_direction_score(self, point, x_offset, y_offset): count = 0 # 落子处我方连续子数 _count = 0 # 落子处对方连续子数 space = None # 我方连续子中有无空格 _space = None # 对方连续子中有无空格 both = 0 # 我方连续子两端有无阻挡 _both = 0 # 对方连续子两端有无阻挡 # 如果是 1 表示是边上是我方子,2 表示敌方子 flag = self._get_stone_color(point, x_offset, y_offset, True) if flag != 0: for step in range(1, 6): x = point.X + step * x_offset y = point.Y + step * y_offset if 0 <= x < self._line_points and 0 <= y < self._line_points: if flag == 1: if self._checkerboard[y][x] == self._my.Value: count += 1 if space is False: space = True elif self._checkerboard[y][x] == self._opponent.Value: _both += 1 break else: if space is None: space = False else: break # 遇到第二个空格退出 elif flag == 2: if self._checkerboard[y][x] == self._my.Value: _both += 1 break elif self._checkerboard[y][x] == self._opponent.Value: _count += 1 if _space is False: _space = True else: if _space is None: _space = False else: break else: # 遇到边也就是阻挡 if flag == 1: both += 1 elif flag == 2: _both += 1 if space is False: space = None if _space is False: _space = None _flag = self._get_stone_color(point, -x_offset, -y_offset, True) if _flag != 0: for step in range(1, 6): x = point.X - step * x_offset y = point.Y - step * y_offset if 0 <= x < self._line_points and 0 <= y < self._line_points: if _flag == 1: if self._checkerboard[y][x] == self._my.Value: count += 1 if space is False: space = True elif self._checkerboard[y][x] == self._opponent.Value: _both += 1 break else: if space is None: space = False else: break # 遇到第二个空格退出 elif _flag == 2: if self._checkerboard[y][x] == self._my.Value: _both += 1 break elif self._checkerboard[y][x] == self._opponent.Value: _count += 1 if _space is False: _space = True else: if _space is None: _space = False else: break else: # 遇到边也就是阻挡 if _flag == 1: both += 1 elif _flag == 2: _both += 1 score = 0 if count == 4: score = 10000 elif _count == 4: score = 9000 elif count == 3: if both == 0: score = 1000 elif both == 1: score = 100 else: score = 0 elif _count == 3: if _both == 0: score = 900 elif _both == 1: score = 90 else: score = 0 elif count == 2: if both == 0: score = 100 elif both == 1: score = 10 else: score = 0 elif _count == 2: if _both == 0: score = 90 elif _both == 1: score = 9 else: score = 0 elif count == 1: score = 10 elif _count == 1: score = 9 else: score = 0 if space or _space: score /= 2 return score # 判断指定位置处在指定方向上是我方子、对方子、空 def _get_stone_color(self, point, x_offset, y_offset, next): x = point.X + x_offset y = point.Y + y_offset if 0 <= x < self._line_points and 0 <= y < self._line_points: if self._checkerboard[y][x] == self._my.Value: return 1 elif self._checkerboard[y][x] == self._opponent.Value: return 2 else: if next: return self._get_stone_color(Point(x, y), x_offset, y_offset, False) else: return 0 else: return 0
8、完善
最后就是对规则的一些完善,比如落子,判断输赢以及胜利界面之类的编写,关键源码如下:
class Checkerboard: def __init__(self, line_points): self._line_points = line_points self._checkerboard = [[0] * line_points for _ in range(line_points)] def _get_checkerboard(self): return self._checkerboard checkerboard = property(_get_checkerboard) # 判断是否可落子 def can_drop(self, point): return self._checkerboard[point.Y][point.X] == 0 def drop(self, chessman, point): """ 落子 :param chessman: :param point:落子位置 :return:若该子落下之后即可获胜,则返回获胜方,否则返回 None """ print(f'{chessman.Name} ({point.X}, {point.Y})') self._checkerboard[point.Y][point.X] = chessman.Value if self._win(point): print(f'{chessman.Name}获胜') return chessman # 判断是否赢了 def _win(self, point): cur_value = self._checkerboard[point.Y][point.X] for os in offset: if self._get_count_on_direction(point, cur_value, os[0], os[1]): return True def _get_count_on_direction(self, point, value, x_offset, y_offset): count = 1 for step in range(1, 5): x = point.X + step * x_offset y = point.Y + step * y_offset if 0 <= x < self._line_points and 0 <= y < self._line_points and self._checkerboard[y][x] == value: count += 1 else: break for step in range(1, 5): x = point.X - step * x_offset y = point.Y - step * y_offset if 0 <= x < self._line_points and 0 <= y < self._line_points and self._checkerboard[y][x] == value: count += 1 else: break return count >= 5
至此,整个游戏就已经制作完成,下面我们可以试玩一下:
说来惭愧,竟不敌人机,再来一局,胜天半子,终于赢了!
总结
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