十年网站开发经验 + 多家企业客户 + 靠谱的建站团队
量身定制 + 运营维护+专业推广+无忧售后,网站问题一站解决
小编这次要给大家分享的是Unity3D如何实现五子棋游戏,文章内容丰富,感兴趣的小伙伴可以来了解一下,希望大家阅读完这篇文章之后能够有所收获。
创新互联建站始终坚持【策划先行,效果至上】的经营理念,通过多达10多年累计超上千家客户的网站建设总结了一套系统有效的全网整合营销推广解决方案,现已广泛运用于各行各业的客户,其中包括:成都水电改造等企业,备受客户称扬。
1 准备工作
(1)开发环境:Win10 + Unity5.4.1
(2)图片素材准备:
黑棋子和白棋子
棋盘
获胜提示图片
2 开发流程
上文提到的素材可以直接下载我们给出的这些图,也可以自己制作。注意黑白棋子要做成PNG格式,以保证显示的时候棋子四个角是透明的。将用到的图片素材导入到工程当中。新建一个场景,创建一个Plane,作为MainCamera的子物体。将棋盘贴图拖动到Plane上,并且将Plane正面面向摄像机。
再创建四个sphere,作为Plane的子物体,分别命名为LeftTop、RightTop、LeftBottom、RightBottom。然后把他们的MeshRenderer勾选掉。这些球是为了计算棋子落点所设置的,所以需要把它们与棋盘的四个角点对准。
然后我们创建一个chess.cs脚本,绑定到MainCamera上。脚本中包含了所有的功能。需要绑定的一些物体如图所示。
chess.cs脚本如下:
using UnityEngine; using System.Collections; public class chess : MonoBehaviour { //四个锚点位置,用于计算棋子落点 public GameObject LeftTop; public GameObject RightTop; public GameObject LeftBottom; public GameObject RightBottom; //主摄像机 public Camera cam; //锚点在屏幕上的映射位置 Vector3 LTPos; Vector3 RTPos; Vector3 LBPos; Vector3 RBPos; Vector3 PointPos;//当前点选的位置 float gridWidth =1; //棋盘网格宽度 float gridHeight=1; //棋盘网格高度 float minGridDis; //网格宽和高中较小的一个 Vector2[,] chessPos; //存储棋盘上所有可以落子的位置 int[,] chessState; //存储棋盘位置上的落子状态 enum turn {black, white } ; turn chessTurn; //落子顺序 public Texture2D white; //白棋子 public Texture2D black; //黑棋子 public Texture2D blackWin; //白子获胜提示图 public Texture2D whiteWin; //黑子获胜提示图 int winner = 0; //获胜方,1为黑子,-1为白子 bool isPlaying = true; //是否处于对弈状态 void Start () { chessPos = new Vector2[15, 15]; chessState =new int[15,15]; chessTurn = turn.black; } void Update () { //计算锚点位置 LTPos = cam.WorldToScreenPoint(LeftTop.transform.position); RTPos = cam.WorldToScreenPoint(RightTop.transform.position); LBPos = cam.WorldToScreenPoint(LeftBottom.transform.position); RBPos = cam.WorldToScreenPoint(RightBottom.transform.position); //计算网格宽度 gridWidth = (RTPos.x - LTPos.x) / 14; gridHeight = (LTPos.y - LBPos.y) / 14; minGridDis = gridWidth < gridHeight ? gridWidth : gridHeight; //计算落子点位置 for (int i = 0; i < 15; i++) { for (int j = 0; j < 15; j++) { chessPos[i, j] = new Vector2(LBPos.x + gridWidth * i, LBPos.y + gridHeight * j); } } //检测鼠标输入并确定落子状态 if (isPlaying && Input.GetMouseButtonDown(0)) { PointPos = Input.mousePosition; for (int i = 0; i < 15; i++) { for (int j = 0; j < 15; j++) { //找到最接近鼠标点击位置的落子点,如果空则落子 if (Dis(PointPos, chessPos[i, j]) < minGridDis / 2 && chessState[i,j]==0) { //根据下棋顺序确定落子颜色 chessState[i, j] = chessTurn == turn.black ? 1 : -1; //落子成功,更换下棋顺序 chessTurn = chessTurn == turn.black ? turn.white : turn.black; } } } //调用判断函数,确定是否有获胜方 int re = result(); if (re == 1) { Debug.Log("黑棋胜"); winner = 1; isPlaying = false; } else if(re==-1) { Debug.Log("白棋胜"); winner = -1; isPlaying = false; } } //按下空格重新开始游戏 if (Input.GetKeyDown(KeyCode.Space)) { for (int i = 0; i < 15; i++) { for (int j = 0; j < 15; j++) { chessState[i, j] = 0; } } isPlaying = true; chessTurn = turn.black; winner = 0; } } //计算平面距离函数 float Dis(Vector3 mPos, Vector2 gridPos) { return Mathf.Sqrt(Mathf.Pow(mPos.x - gridPos.x, 2)+ Mathf.Pow(mPos.y - gridPos.y, 2)); } void OnGUI() { //绘制棋子 for(int i=0;i<15;i++) { for (int j = 0; j < 15; j++) { if (chessState[i, j] == 1) { GUI.DrawTexture(new Rect(chessPos[i,j].x-gridWidth/2, Screen.height-chessPos[i,j].y-gridHeight/2, gridWidth,gridHeight),black); } if (chessState[i, j] == -1) { GUI.DrawTexture(new Rect(chessPos[i, j].x - gridWidth / 2, Screen.height - chessPos[i, j].y - gridHeight / 2, gridWidth, gridHeight), white); } } } //根据获胜状态,弹出相应的胜利图片 if (winner == 1) GUI.DrawTexture(new Rect(Screen.width * 0.25f, Screen.height * 0.25f, Screen.width * 0.5f, Screen.height * 0.25f), blackWin); if (winner == -1) GUI.DrawTexture(new Rect(Screen.width * 0.25f, Screen.height * 0.25f, Screen.width * 0.5f, Screen.height * 0.25f), whiteWin); } //检测是够获胜的函数,不含黑棋禁手检测 int result() { int flag = 0; //如果当前该白棋落子,标定黑棋刚刚下完一步,此时应该判断黑棋是否获胜 if(chessTurn == turn.white) { for (int i = 0; i < 11; i++) { for (int j = 0; j < 15; j++) { if (j < 4) { //横向 if (chessState[i, j] == 1 && chessState[i, j + 1] == 1 && chessState[i, j + 2] == 1 && chessState[i, j + 3] == 1 && chessState[i, j + 4] == 1) { flag = 1; return flag; } //纵向 if (chessState[i, j] == 1 && chessState[i + 1, j] == 1 && chessState[i + 2, j] == 1 && chessState[i + 3, j] == 1 && chessState[i + 4, j] == 1) { flag = 1; return flag; } //右斜线 if (chessState[i, j] == 1 && chessState[i + 1, j + 1] == 1 && chessState[i + 2, j + 2] == 1 && chessState[i + 3, j + 3] == 1 && chessState[i + 4, j + 4] == 1) { flag = 1; return flag; } //左斜线 //if (chessState[i, j] == 1 && chessState[i + 1, j - 1] == 1 && chessState[i + 2, j - 2] == 1 && chessState[i + 3, j - 3] == 1 && chessState[i + 4, j - 4] == 1) //{ // flag = 1; // return flag; //} } else if (j >= 4 && j < 11) { //横向 if (chessState[i, j] == 1 && chessState[i, j + 1] == 1 && chessState[i, j + 2] == 1 && chessState[i, j + 3] == 1 && chessState[i, j + 4] == 1) { flag = 1; return flag; } //纵向 if (chessState[i, j] == 1 && chessState[i + 1, j] == 1 && chessState[i + 2, j] == 1 && chessState[i + 3, j] == 1 && chessState[i + 4, j] == 1) { flag = 1; return flag; } //右斜线 if (chessState[i, j] == 1 && chessState[i + 1, j + 1] == 1 && chessState[i + 2, j + 2] == 1 && chessState[i + 3, j + 3] == 1 && chessState[i + 4, j + 4] == 1) { flag = 1; return flag; } //左斜线 if (chessState[i, j] == 1 && chessState[i + 1, j - 1] == 1 && chessState[i + 2, j - 2] == 1 && chessState[i + 3, j - 3] == 1 && chessState[i + 4, j - 4] == 1) { flag = 1; return flag; } } else { //横向 //if (chessState[i, j] == 1 && chessState[i, j + 1] == 1 && chessState[i, j + 2] == 1 && chessState[i, j + 3] == 1 && chessState[i, j + 4] == 1) //{ // flag = 1; // return flag; //} //纵向 if (chessState[i, j] == 1 && chessState[i + 1, j] == 1 && chessState[i + 2, j] == 1 && chessState[i + 3, j] == 1 && chessState[i + 4, j] == 1) { flag = 1; return flag; } //右斜线 //if (chessState[i, j] == 1 && chessState[i + 1, j + 1] == 1 && chessState[i + 2, j + 2] == 1 && chessState[i + 3, j + 3] == 1 && chessState[i + 4, j + 4] == 1) //{ // flag = 1; // return flag; //} //左斜线 if (chessState[i, j] == 1 && chessState[i + 1, j - 1] == 1 && chessState[i + 2, j - 2] == 1 && chessState[i + 3, j - 3] == 1 && chessState[i + 4, j - 4] == 1) { flag = 1; return flag; } } } } for (int i = 11; i < 15; i++) { for (int j = 0; j < 11; j++) { //只需要判断横向 if (chessState[i, j] == 1 && chessState[i, j + 1] == 1 && chessState[i, j + 2] == 1 && chessState[i, j + 3] == 1 && chessState[i, j + 4] == 1) { flag = 1; return flag; } } } } //如果当前该黑棋落子,标定白棋刚刚下完一步,此时应该判断白棋是否获胜 else if(chessTurn == turn.black) { for (int i = 0; i < 11; i++) { for (int j = 0; j < 15; j++) { if (j < 4) { //横向 if (chessState[i, j] == -1 && chessState[i, j + 1] == -1 && chessState[i, j + 2] == -1 && chessState[i, j + 3] == -1 && chessState[i, j + 4] == -1) { flag = -1; return flag; } //纵向 if (chessState[i, j] == -1 && chessState[i + 1, j] == -1 && chessState[i + 2, j] == -1 && chessState[i + 3, j] == -1 && chessState[i + 4, j] == -1) { flag = -1; return flag; } //右斜线 if (chessState[i, j] == -1 && chessState[i + 1, j + 1] == -1 && chessState[i + 2, j + 2] == -1 && chessState[i + 3, j + 3] == -1 && chessState[i + 4, j + 4] == -1) { flag = -1; return flag; } //左斜线 //if (chessState[i, j] == -1 && chessState[i + 1, j - 1] == -1 && chessState[i + 2, j - 2] == -1 && chessState[i + 3, j - 3] == -1 && chessState[i + 4, j - 4] == -1) //{ // flag = -1; // return flag; //} } else if (j >= 4 && j < 11) { //横向 if (chessState[i, j] == -1 && chessState[i, j + 1] == -1 && chessState[i, j + 2] == -1 && chessState[i, j + 3] == -1 && chessState[i, j + 4] ==- 1) { flag = -1; return flag; } //纵向 if (chessState[i, j] == -1 && chessState[i + 1, j] == -1 && chessState[i + 2, j] == -1 && chessState[i + 3, j] == -1 && chessState[i + 4, j] == -1) { flag = -1; return flag; } //右斜线 if (chessState[i, j] == -1 && chessState[i + 1, j + 1] == -1 && chessState[i + 2, j + 2] == -1 && chessState[i + 3, j + 3] == -1 && chessState[i + 4, j + 4] == -1) { flag = -1; return flag; } //左斜线 if (chessState[i, j] == -1 && chessState[i + 1, j - 1] == -1 && chessState[i + 2, j - 2] == -1 && chessState[i + 3, j - 3] == -1 && chessState[i + 4, j - 4] == -1) { flag = -1; return flag; } } else { //横向 //if (chessState[i, j] == -1 && chessState[i, j + 1] ==- 1 && chessState[i, j + 2] == -1 && chessState[i, j + 3] == -1 && chessState[i, j + 4] == -1) //{ // flag = -1; // return flag; //} //纵向 if (chessState[i, j] == -1 && chessState[i + 1, j] ==- 1 && chessState[i + 2, j] ==- 1 && chessState[i + 3, j] ==- 1 && chessState[i + 4, j] == -1) { flag = -1; return flag; } //右斜线 //if (chessState[i, j] == -1 && chessState[i + 1, j + 1] == -1 && chessState[i + 2, j + 2] == -1 && chessState[i + 3, j + 3] == -1 && chessState[i + 4, j + 4] == -1) //{ // flag = -1; // return flag; //} //左斜线 if (chessState[i, j] == -1 && chessState[i + 1, j - 1] == -1 && chessState[i + 2, j - 2] == -1 && chessState[i + 3, j - 3] == -1 && chessState[i + 4, j - 4] == -1) { flag = -1; return flag; } } } } for (int i = 11; i < 15; i++) { for (int j = 0; j < 11; j++) { //只需要判断横向 if (chessState[i, j] == -1 && chessState[i, j + 1] == -1 && chessState[i, j + 2] == -1 && chessState[i, j + 3] == -1 && chessState[i, j + 4] == -1) { flag = -1; return flag; } } } } return flag; } }
运行效果截图:
小结
本程序实现了五子棋的基本功能,纯属娱乐而作。暂时没有加入各种UI、网络模块等。本程序经过了简单的测试,没有什么问题,如果大家在使用的时候发现有什么Bug,请联系我改正,谢谢。
看完这篇关于Unity3D如何实现五子棋游戏的文章,如果觉得文章内容写得不错的话,可以把它分享出去给更多人看到。