这里的逻辑核心是需要判断方块是否碰撞(当前运动的方块和已经定位好的方块有碰撞以致于当前的运动的方块不能在向下走,因为我们的方块默认是向下走的,如果不能向下走,是视为已经定位好的方块,然后在生成一个新的方块从初始位置继续往下走)。
<!DOCTYPE html>
<html lang="en">
<head>
<meta charset="UTF-8">
<title>es6-重构俄罗斯方块(基于canvas)</title>
<style type="text/css">
#tetris{ margin: 10px 250px;}
</style>
</head>
<body>
<canvas width="700" height="525" id="tetris"></canvas>
<div id="text" style='color: red;font-size: 30px;'>当前分数:0</div>
<script type="text/javascript">
/**
* [一个完整的俄罗斯方块类 design by magic_xiang]
* @param {number} side [每个方块边长(px),默认35]
* @param {number} width [一行包含的方块数(个),默认20]
* @param {number} height [一列包含的方块数(个),默认15]
* @param {number} speed [方块下落移动速度(ms),默认400]
*/
class tetris{
constructor(side=35, width=20, height=15, speed=400){
this.side = side // 每个方块边长
this.width = width // 一行包含的方块数
this.height = height // 一列包含的方块数
this.speed = speed // 方块下落移动速度
this.num_blcok // 当前方块类型的数字变量
this.type_color // 当前颜色类型的字符串变量
this.ident // setInterval的标识
this.direction = 1 // 方块方向,初始化为1,默认状态
this.grade = 0 // 用来计算分数
this.over = false // 游戏是否结束
this.arr_bX = [] // 存放当前方块的X坐标
this.arr_bY = [] // 存放当前方块的Y坐标
this.arr_store_X = [] // 存放到达底部所有方块的X坐标
this.arr_store_Y = [] // 存放到达底部所有方块的Y坐标
this.arr_store_color = [] // 存放到达底部所有方块的颜色
this.paints = document.getElementById('tetris').getContext('2d')
//获取画笔
self = this
}
// 封装paints方法,让代码更简洁
paintfr(x, y, scale=1){
this.paints.fillRect(x*this.side, y*this.side, scale*this.side, scale*this.side)
}
// 游戏开始
gameStart(){
this.init()
this.run()
}
// 初始化工作
init(){
this.initBackground()
this.initBlock()
}
// 方块自动下落
run(){
this.ident = setInterval("self.down_speed_up()", this.speed)
}
// 初始化地图
initBackground(){
this.paints.beginPath()
this.paints.fillStyle='#000000' //地图填充颜色为黑色
for(let i = 0; i < this.height; i++){
for(let j = 0; j < this.width; j++){
this.paintfr(j, i)
}
}
this.paints.closePath()
}
// 初始化方块的位置和颜色
initBlock(){
this.paints.beginPath()
this.createRandom('rColor') //生成颜色字符串,
this.paints.fillStyle = this.type_color
this.createRandom('rBlock') //生成方块类型数字
this.arr_bX.forEach((item, index) => {
this.paintfr(item, this.arr_bY[index], 0.9)
})
this.paints.closePath()
}
// 利用数组画方块
drawBlock(color){
this.paints.beginPath()
this.paints.fillStyle = color
this.arr_bX.forEach((item, index) => {
this.paintfr(item, this.arr_bY[index], 0.9)
})
this.paints.closePath()
}
// 画已经在定位好的方块
drawStaticBlock(){
this.arr_store_X.forEach((item, index) => {
this.paints.beginPath()
this.paints.fillStyle = this.arr_store_color[index]
this.paintfr(item, this.arr_store_Y[index], 0.9)
this.paints.closePath()
})
}
// 生成随机数返回方块类型或颜色类型
createRandom(type){
let temp = this.width/2-1
if (type == 'rBlock'){ //如果是方块类型
this.num_blcok = Math.round(Math.random()*4+1)
switch(this.num_blcok){
case 1:
this.arr_bX.push(temp,temp-1,temp,temp+1)
this.arr_bY.push(0,1,1,1)
break
case 2:
this.arr_bX.push(temp,temp-1,temp-1,temp+1)
this.arr_bY.push(1,0,1,1)
break
case 3:
this.arr_bX.push(temp,temp-1,temp+1,temp+2)
this.arr_bY.push(0,0,0,0)
break
case 4:
this.arr_bX.push(temp,temp-1,temp,temp+1)
this.arr_bY.push(0,0,1,1)
break
case 5:
this.arr_bX.push(temp,temp+1,temp,temp+1)
this.arr_bY.push(0,0,1,1)
break
}
}
if (type == 'rColor'){ //如果是颜色类型
let num_color = Math.round(Math.random()*8+1)
switch(num_color){
case 1:
this.type_color='#3EF72A'
break
case 2:
this.type_color='yellow'
break
case 3:
this.type_color='#2FE0BF'
break
case 4:
this.type_color='red'
break
case 5:
this.type_color='gray'
break
case 6:
this.type_color='#C932C6'
break
case 7:
this.type_color= '#FC751B'
break
case 8:
this.type_color= '#6E6EDD'
break
case 9:
this.type_color= '#F4E9E1'
break
}
}
}
// 判断方块之间是否碰撞(下),以及变形时是否越过下边界
judgeCollision_down(){
for(let i = 0; i < this.arr_bX.length; i++){
if (this.arr_bY[i] + 1 == this.height){ //变形时是否越过下边界
return false
}
if (this.arr_store_X.length != 0) { //判断方块之间是否碰撞(下)
for(let j = 0; j < this.arr_store_X.length; j++){
if (this.arr_bX[i] == this.arr_store_X[j]) {
if (this.arr_bY[i] + 1 == this.arr_store_Y[j]) {
return false
}
}
}
}
}
return true
}
//判断方块之间是否碰撞(左右),以及变形时是否越过左右边界
judgeCollision_other(num){
for(let i = 0; i < this.arr_bX.length; i++){
if (num == 1) { //变形时是否越过右边界
if (this.arr_bX[i] == this.width - 1)
return false
}
if (num == -1) { //变形时是否越过左边界
if (this.arr_bX[i] == 0)
return false
}
if (this.arr_store_X.length != 0) { //判断方块之间是否碰撞(左右)
for(let j = 0; j < this.arr_store_X.length; j++){
if (this.arr_bY[i] == this.arr_store_Y[j]) {
if (this.arr_bX[i] + num == this.arr_store_X[j]) {
return false
}
}
}
}
}
return true;
}
//方向键为下的加速函数
down_speed_up(){
let flag_all_down = true
flag_all_down = this.judgeCollision_down()
if (flag_all_down) {
this.initBackground()
for(let i = 0; i < this.arr_bY.length; i++){
this.arr_bY[i] = this.arr_bY[i] + 1
}
}
else{
for(let i=0; i < this.arr_bX.length; i++){
this.arr_store_X.push(this.arr_bX[i])
this.arr_store_Y.push(this.arr_bY[i])
this.arr_store_color.push(this.type_color)
}
this.arr_bX.splice(0,this.arr_bX.length)
this.arr_bY.splice(0,this.arr_bY.length)
this.initBlock()
}
this.clearUnderBlock()
this.drawBlock(this.type_color)
this.drawStaticBlock()
this.gameover()
}
//方向键为左右的左移动函数
move(dir_temp){
this.initBackground()
if (dir_temp == 1) { //右
let flag_all_right = true
flag_all_right = this.judgeCollision_other(1)
if (flag_all_right) {
for(let i = 0; i < this.arr_bY.length; i++){
this.arr_bX[i] = this.arr_bX[i]+1
}
}
}
else{
let flag_all_left = true
flag_all_left = this.judgeCollision_other(-1)
if (flag_all_left) {
for(let i=0; i < this.arr_bY.length; i++){
this.arr_bX[i] = this.arr_bX[i]-1
}
}
}
this.drawBlock(this.type_color)
this.drawStaticBlock()
}
//方向键为空格的变换方向函数
up_change_direction(num_blcok){
if (num_blcok == 5) {
return
}
let arr_tempX = []
let arr_tempY = []
//因为不知道是否能够变形成功,所以先存储起来
for(let i = 0;i < this.arr_bX.length; i++){
arr_tempX.push(this.arr_bX[i])
arr_tempY.push(this.arr_bY[i])
}
this.direction++
//将中心坐标提取出来,变形都以当前中心为准
let ax_temp = this.arr_bX[0]
let ay_temp = this.arr_bY[0]
this.arr_bX.splice(0, this.arr_bX.length) //将数组清空
this.arr_bY.splice(0, this.arr_bY.length)
if (num_blcok == 1) {
switch(this.direction%4){
case 1:
this.arr_bX.push(ax_temp,ax_temp-1,ax_temp,ax_temp+1)
this.arr_bY.push(ay_temp,ay_temp+1,ay_temp+1,ay_temp+1)
break
case 2:
this.arr_bX.push(ax_temp,ax_temp-1,ax_temp,ax_temp)
this.arr_bY.push(ay_temp,ay_temp,ay_temp-1,ay_temp+1)
break
case 3:
this.arr_bX.push(ax_temp,ax_temp-1,ax_temp,ax_temp+1)
this.arr_bY.push(ay_temp,ay_temp,ay_temp+1,ay_temp)
break
case 0:
this.arr_bX.push(ax_temp,ax_temp,ax_temp,ax_temp+1)
this.arr_bY.push(ay_temp,ay_temp-1,ay_temp+1,ay_temp)
break
}
}
if (num_blcok == 2) {
switch(this.direction%4){
case 1:
this.arr_bX.push(ax_temp,ax_temp-1,ax_temp-1,ax_temp+1)
this.arr_bY.push(ay_temp,ay_temp,ay_temp-1,ay_temp)
break
case 2:
this.arr_bX.push(ax_temp,ax_temp,ax_temp,ax_temp-1)
this.arr_bY.push(ay_temp,ay_temp-1,ay_temp+1,ay_temp+1)
break
case 3:
this.arr_bX.push(ax_temp,ax_temp-1,ax_temp+1,ax_temp+1)
this.arr_bY.push(ay_temp,ay_temp,ay_temp,ay_temp+1)
break
case 0:
this.arr_bX.push(ax_temp,ax_temp,ax_temp,ax_temp+1)
this.arr_bY.push(ay_temp,ay_temp-1,ay_temp+1,ay_temp-1)
break
}
}
if (num_blcok == 3) {
switch(this.direction%4){
case 1:
this.arr_bX.push(ax_temp,ax_temp-1,ax_temp+1,ax_temp+2)
this.arr_bY.push(ay_temp,ay_temp,ay_temp,ay_temp)
break
case 2:
this.arr_bX.push(ax_temp,ax_temp,ax_temp,ax_temp)
this.arr_bY.push(ay_temp,ay_temp-1,ay_temp+1,ay_temp+2)
break
case 3:
this.arr_bX.push(ax_temp,ax_temp-1,ax_temp+1,ax_temp+2)
this.arr_bY.push(ay_temp,ay_temp,ay_temp,ay_temp)
break
case 0:
this.arr_bX.push(ax_temp,ax_temp,ax_temp,ax_temp)
this.arr_bY.push(ay_temp,ay_temp-1,ay_temp+1,ay_temp+2)
break
}
}
if (num_blcok == 4) {
switch(this.direction%4){
case 1:
this.arr_bX.push(ax_temp,ax_temp-1,ax_temp,ax_temp+1)
this.arr_bY.push(ay_temp,ay_temp,ay_temp+1,ay_temp+1)
break
case 2:
this.arr_bX.push(ax_temp,ax_temp,ax_temp+1,ax_temp+1)
this.arr_bY.push(ay_temp,ay_temp+1,ay_temp,ay_temp-1)
break
case 3:
this.arr_bX.push(ax_temp,ax_temp,ax_temp-1,ax_temp+1)
this.arr_bY.push(ay_temp,ay_temp-1,ay_temp,ay_temp-1)
break
case 0:
this.arr_bX.push(ax_temp,ax_temp,ax_temp+1,ax_temp+1)
this.arr_bY.push(ay_temp,ay_temp-1,ay_temp,ay_temp+1)
break
}
}
if (! (this.judgeCollision_other(-1) && this.judgeCollision_down() && this.judgeCollision_other(1) )) { //如果变形不成功则执行下面代码
this.arr_bX.splice(0, this.arr_bX.length)
this.arr_bY.splice(0, this.arr_bY.length)
for(let i=0; i< arr_tempX.length; i++){
this.arr_bX.push(arr_tempX[i])
this.arr_bY.push(arr_tempY[i])
}
}
this.drawStaticBlock()
}
//一行满了清空方块,上面方块Y坐标+1
clearUnderBlock(){
//删除低层方块
let arr_row=[]
let line_num
if (this.arr_store_X.length != 0) {
for(let j = this.height-1; j >= 0; j--){
for(let i = 0; i < this.arr_store_color.length; i++){
if (this.arr_store_Y[i] == j) {
arr_row.push(i)
}
}
if (arr_row.length == this.width) {
line_num = j
break
}else{
arr_row.splice(0, arr_row.length)
}
}
}
if (arr_row.length == this.width) {
//计算成绩grade
this.grade++
document.getElementById('text').innerHTML = '当前成绩:'+this.grade
for(let i = 0; i < arr_row.length; i++){
this.arr_store_X.splice(arr_row[i]-i, 1)
this.arr_store_Y.splice(arr_row[i]-i, 1)
this.arr_store_color.splice(arr_row[i]-i, 1)
}
//让上面的方块往下掉一格
for(let i = 0; i < this.arr_store_color.length; i++){
if (this.arr_store_Y[i] < line_num) {
this.arr_store_Y[i] = this.arr_store_Y[i]+1
}
}
}
}
//判断游戏结束
gameover(){
for(let i=0; i < this.arr_store_X.length; i++){
if (this.arr_store_Y[i] == 0) {
clearInterval(this.ident)
this.over = true
}
}
}
}
let tetrisObj = new tetris()
tetrisObj.gameStart()
//方向键功能函数
document.onkeydown = (e) => {
if (tetrisObj.over)
return
switch(e.keyCode){
case 40: // 方向为下
tetrisObj.down_speed_up()
break
case 32: // 空格换方向
tetrisObj.initBackground() //重画地图
tetrisObj.up_change_direction(tetrisObj.num_blcok)
tetrisObj.drawBlock(tetrisObj.type_color)
break
case 37: // 方向为左
tetrisObj.initBackground()
tetrisObj.move(-1)
tetrisObj.drawBlock(tetrisObj.type_color)
break
case 39: // 方向为右
tetrisObj.initBackground()
tetrisObj.move(1)
tetrisObj.drawBlock(tetrisObj.type_color)
break
}
}
</script>
</body>
</html>
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