package noah;
import java.io.BufferedReader;
import java.io.FileInputStream;
import java.io.IOException;
import java.io.InputStreamReader;
public class TxTsp {
private int cityNum; // 城市数量
private int[][] distance; // 距离矩阵
private int[] colable;//代表列,也表示是否走过,走过置0
private int[] row;//代表行,选过置0
public TxTsp(int n) {
cityNum = n;
}
private void init(String filename) throws IOException {
// 读取数据
int[] x;
int[] y;
String strbuff;
BufferedReader data = new BufferedReader(new InputStreamReader(
new FileInputStream(filename)));
distance = new int[cityNum][cityNum];
x = new int[cityNum];
y = new int[cityNum];
for (int i = 0; i < cityNum; i++) {
// 读取一行数据,数据格式1 6734 1453
strbuff = data.readLine();
// 字符分割
String[] strcol = strbuff.split(" ");
x[i] = Integer.valueOf(strcol[1]);// x坐标
y[i] = Integer.valueOf(strcol[2]);// y坐标
}
data.close();
// 计算距离矩阵
// ,针对具体问题,距离计算方法也不一样,此处用的是att48作为案例,它有48个城市,距离计算方法为伪欧氏距离,最优值为10628
for (int i = 0; i < cityNum - 1; i++) {
distance[i][i] = 0; // 对角线为0
for (int j = i + 1; j < cityNum; j++) {
double rij = Math
.sqrt(((x[i] - x[j]) * (x[i] - x[j]) + (y[i] - y[j])
* (y[i] - y[j])) / 10.0);
// 四舍五入,取整
int tij = (int) Math.round(rij);
if (tij < rij) {
distance[i][j] = tij + 1;
distance[j][i] = distance[i][j];
} else {
distance[i][j] = tij;
distance[j][i] = distance[i][j];
}
}
}
distance[cityNum - 1][cityNum - 1] = 0;
colable = new int[cityNum];
colable[0] = 0;
for (int i = 1; i < cityNum; i++) {
colable[i] = 1;
}
row = new int[cityNum];
for (int i = 0; i < cityNum; i++) {
row[i] = 1;
}
}
public void solve(){
int[] temp = new int[cityNum];
String path="0";
int s=0;//计算距离
int i=0;//当前节点
int j=0;//下一个节点
//默认从0开始
while(row[i]==1){
//复制一行
for (int k = 0; k < cityNum; k++) {
temp[k] = distance[i][k];
//System.out.print(temp[k]+" ");
}
//System.out.println();
//选择下一个节点,要求不是已经走过,并且与i不同
j = selectmin(temp);
//找出下一节点
row[i] = 0;//行置0,表示已经选过
colable[j] = 0;//列0,表示已经走过
path+="-->" + j;
//System.out.println(i + "-->" + j);
//System.out.println(distance[i][j]);
s = s + distance[i][j];
i = j;//当前节点指向下一节点
}
System.out.println("路径:" + path);
System.out.println("总距离为:" + s);
}
public int selectmin(int[] p){
int j = 0, m = p[0], k = 0;
//寻找第一个可用节点,注意最后一次寻找,没有可用节点
while (colable[j] == 0) {
j++;
//System.out.print(j+" ");
if(j>=cityNum){
//没有可用节点,说明已结束,最后一次为 *-->0
m = p[0];
break;
//或者直接return 0;
}
else{
m = p[j];
}
}
//从可用节点J开始往后扫描,找出距离最小节点
for (; j < cityNum; j++) {
if (colable[j] == 1) {
if (m >= p[j]) {
m = p[j];
k = j;
}
}
}
return k;
}
public void printinit() {
System.out.println("print begin....");
for (int i = 0; i < cityNum; i++) {
for (int j = 0; j < cityNum; j++) {
System.out.print(distance[i][j] + " ");
}
System.out.println();
}
System.out.println("print end....");
}
public static void main(String[] args) throws IOException {
System.out.println("Start....");
TxTsp ts = new TxTsp(48);
ts.init("c://data.txt");
//ts.printinit();
ts.solve();
}
}
❷ java经典算法题——猴子吃桃
main()
{
int day,x1,x2;
day=9;
x2=1;
while(day>0)
{x1=(x2+1)*2;/*第一天的桃子数是第2天桃子数加1后的2倍*/
x2=x1;
day--;
}
print("the total is "+x1);
}
❸ java算法面试题:排序都有哪几种方法
一、冒泡排序
[java] view plain
package sort.bubble;
import java.util.Random;
/**
* 依次比较相邻的两个数,将小数放在前面,大数放在后面
* 冒泡排序,具有稳定性
* 时间复杂度为O(n^2)
* 不及堆排序,快速排序O(nlogn,底数为2)
* @author liangge
*
*/
public class Main {
public static void main(String[] args) {
Random ran = new Random();
int[] sort = new int[10];
for(int i = 0 ; i < 10 ; i++){
sort[i] = ran.nextInt(50);
}
System.out.print("排序前的数组为");
for(int i : sort){
System.out.print(i+" ");
}
buddleSort(sort);
System.out.println();
System.out.print("排序后的数组为");
for(int i : sort){
System.out.print(i+" ");
}
}
/**
* 冒泡排序
* @param sort
*/
private static void buddleSort(int[] sort){
for(int i=1;i<sort.length;i++){
for(int j=0;j<sort.length-i;j++){
if(sort[j]>sort[j+1]){
int temp = sort[j+1];
sort[j+1] = sort[j];
sort[j] = temp;
}
}
}
}
}
二、选择排序
[java] view plain
package sort.select;
import java.util.Random;
/**
* 选择排序
* 每一趟从待排序的数据元素中选出最小(或最大)的一个元素,
* 顺序放在已排好序的数列的最后,直到全部待排序的数据元素排完。
* 选择排序是不稳定的排序方法。
* @author liangge
*
*/
public class Main {
public static void main(String[] args) {
Random ran = new Random();
int[] sort = new int[10];
for (int i = 0; i < 10; i++) {
sort[i] = ran.nextInt(50);
}
System.out.print("排序前的数组为");
for (int i : sort) {
System.out.print(i + " ");
}
selectSort(sort);
System.out.println();
System.out.print("排序后的数组为");
for (int i : sort) {
System.out.print(i + " ");
}
}
/**
* 选择排序
* @param sort
*/
private static void selectSort(int[] sort){
for(int i =0;i<sort.length-1;i++){
for(int j = i+1;j<sort.length;j++){
if(sort[j]<sort[i]){
int temp = sort[j];
sort[j] = sort[i];
sort[i] = temp;
}
}
}
}
}
三、快速排序
[java] view plain
package sort.quick;
/**
* 快速排序 通过一趟排序将要排序的数据分割成独立的两部分, 其中一部分的所有数据都比另外一部分的所有数据都要小,
* 然后再按此方法对这两部分数据分别进行快速排序, 整个排序过程可以递归进行,以此达到整个数据变成有序序列。
* @author liangge
*
*/
public class Main {
public static void main(String[] args) {
int[] sort = { 54, 31, 89, 33, 66, 12, 68, 20 };
System.out.print("排序前的数组为:");
for (int data : sort) {
System.out.print(data + " ");
}
System.out.println();
quickSort(sort, 0, sort.length - 1);
System.out.print("排序后的数组为:");
for (int data : sort) {
System.out.print(data + " ");
}
}
/**
* 快速排序
* @param sort 要排序的数组
* @param start 排序的开始座标
* @param end 排序的结束座标
*/
public static void quickSort(int[] sort, int start, int end) {
// 设置关键数据key为要排序数组的第一个元素,
// 即第一趟排序后,key右边的数全部比key大,key左边的数全部比key小
int key = sort[start];
// 设置数组左边的索引,往右移动判断比key大的数
int i = start;
// 设置数组右边的索引,往左移动判断比key小的数
int j = end;
// 如果左边索引比右边索引小,则还有数据没有排序
while (i < j) {
while (sort[j] > key && j > start) {
j--;
}
while (sort[i] < key && i < end) {
i++;
}
if (i < j) {
int temp = sort[i];
sort[i] = sort[j];
sort[j] = temp;
}
}
// 如果左边索引比右边索引要大,说明第一次排序完成,将sort[j]与key对换,
// 即保持了key左边的数比key小,key右边的数比key大
if (i > j) {
int temp = sort[j];
sort[j] = sort[start];
sort[start] = temp;
}
//递归调用
if (j > start && j < end) {
quickSort(sort, start, j - 1);
quickSort(sort, j + 1, end);
}
}
}
[java] view plain
/**
* 快速排序
*
* @param a
* @param low
* @param high
* voidTest
*/
public static void kuaisuSort(int[] a, int low, int high)
{
if (low >= high)
{
return;
}
if ((high - low) == 1)
{
if (a[low] > a[high])
{
swap(a, low, high);
return;
}
}
int key = a[low];
int left = low + 1;
int right = high;
while (left < right)
{
while (left < right && left <= high)// 左边向右
{
if (a[left] >= key)
{
break;
}
left++;
}
while (right >= left && right > low)
{
if (a[right] <= key)
{
break;
}
right--;
}
if (left < right)
{
swap(a, left, right);
}
}
swap(a, low, right);
kuaisuSort(a, low, right);
kuaisuSort(a, right + 1, high);
}
四、插入排序
[java] view plain
package sort.insert;
/**
* 直接插入排序
* 将一个数据插入到已经排好序的有序数据中,从而得到一个新的、个数加一的有序数据
* 算法适用于少量数据的排序,时间复杂度为O(n^2)。是稳定的排序方法。
*/
import java.util.Random;
public class DirectMain {
public static void main(String[] args) {
Random ran = new Random();
int[] sort = new int[10];
for (int i = 0; i < 10; i++) {
sort[i] = ran.nextInt(50);
}
System.out.print("排序前的数组为");
for (int i : sort) {
System.out.print(i + " ");
}
directInsertSort(sort);
System.out.println();
System.out.print("排序后的数组为");
for (int i : sort) {
System.out.print(i + " ");
}
}
/**
* 直接插入排序
*
* @param sort
*/
private static void directInsertSort(int[] sort) {
for (int i = 1; i < sort.length; i++) {
int index = i - 1;
int temp = sort[i];
while (index >= 0 && sort[index] > temp) {
sort[index + 1] = sort[index];
index--;
}
sort[index + 1] = temp;
}
}
}
顺便添加一份,差不多的
[java] view plain
public static void charuSort(int[] a)
{
int len = a.length;
for (int i = 1; i < len; i++)
{
int j;
int temp = a[i];
for (j = i; j > 0; j--)//遍历i之前的数字
{
//如果之前的数字大于后面的数字,则把大的值赋到后面
if (a[j - 1] > temp)
{
a[j] = a[j - 1];
} else
{
break;
}
}
a[j] = temp;
}
}
把上面整合起来的一份写法:
[java] view plain
/**
* 插入排序:
*
*/
public class InsertSort {
public void sort(int[] data) {
for (int i = 1; i < data.length; i++) {
for (int j = i; (j > 0) && (data[j] < data[j - 1]); j--) {
swap(data, j, j - 1);
}
}
}
private void swap(int[] data, int i, int j) {
int temp = data[i];
data[i] = data[j];
data[j] = temp;
}
}
五、顺便贴个二分搜索法
[java] view plain
package search.binary;
public class Main {
public static void main(String[] args) {
int[] sort = {1,2,3,4,5,6,7,8,9,10};
int mask = binarySearch(sort,6);
System.out.println(mask);
}
/**
* 二分搜索法,返回座标,不存在返回-1
* @param sort
* @return
*/
private static int binarySearch(int[] sort,int data){
if(data<sort[0] || data>sort[sort.length-1]){
return -1;
}
int begin = 0;
int end = sort.length;
int mid = (begin+end)/2;
while(begin <= end){
mid = (begin+end)/2;
if(data > sort[mid]){
begin = mid + 1;
}else if(data < sort[mid]){
end = mid - 1;
}else{
return mid;
}
}
return -1;
}
}
❹ Java迷宫算法问题(用栈实现)有算法简述
importjava.io.File;
importjava.io.FileNotFoundException;
importjava.util.HashSet;
importjava.util.LinkedList;
importjava.util.List;
importjava.util.Scanner;
publicclassTest{
publicstaticvoidmain(String[]args)throwsFileNotFoundException{
Scannerinput=newScanner(newFile("Maze2tong.txt"));
introw=0;
char[][]Mazemap=newchar[12][58];
while(input.hasNext()){
Stringline=input.nextLine();
for(intcolumn=0;column<=line.length()-1;column++){
charc=line.charAt(column);
Mazemap[row][column]=c;
}
row++;
}
for(inti=0;i<12;i++){
for(intj=0;j<58;j++){
System.out.print(Mazemap[i][j]);
}
System.out.print(" ");
}
LinkedList<TwoTuple<Integer,Integer>>trace=newLinkedList<TwoTuple<Integer,Integer>>();
System.out.println(maze(Mazemap,trace));
System.out.println(trace);
}
publicstaticbooleanmaze(char[][]maze,
List<TwoTuple<Integer,Integer>>trace){
LinkedList<TwoTuple<Integer,Integer>>path=newLinkedList<TwoTuple<Integer,Integer>>();
HashSet<TwoTuple<Integer,Integer>>traverse=newHashSet<TwoTuple<Integer,Integer>>();
for(inti=0;i<maze.length;i++){
for(intj=0;j<maze[i].length;j++){
if(maze[i][j]=='S'){
path.add(newTwoTuple<Integer,Integer>(i,j));
}
}
}
while(!path.isEmpty()){
TwoTuple<Integer,Integer>temp=path.pop();
if(traverse.contains(temp)){
continue;
}elseif(maze[temp.first][temp.second]=='F'){
trace.add(temp);
returntrue;
}elseif(!traverse.contains(temp)){
if(temp.second+1<maze[temp.first].length
&&maze[temp.first][temp.second+1]!='W')
path.add(newTwoTuple<Integer,Integer>(temp.first,
temp.second+1));
if(temp.second-1>0
&&maze[temp.first][temp.second-1]!='W')
path.add(newTwoTuple<Integer,Integer>(temp.first,
temp.second-1));
if(temp.first+1<maze.length
&&maze[temp.first+1][temp.second]!='W')
path.add(newTwoTuple<Integer,Integer>(temp.first+1,
temp.second));
if(temp.first-1>0
&&maze[temp.first-1][temp.second]!='W')
path.add(newTwoTuple<Integer,Integer>(temp.first-1,
temp.second));
traverse.add(temp);
trace.add(temp);
}
}
trace.clear();
returnfalse;
}
}
classTwoTuple<A,B>{
publicfinalAfirst;
publicfinalBsecond;
publicTwoTuple(Aa,Bb){
first=a;
second=b;
}
@Override
publicinthashCode(){
returnfirst.hashCode()+second.hashCode();
}
@Override
publicbooleanequals(Objectobj){
if(!(objinstanceofTwoTuple)){
}
returnobjinstanceofTwoTuple&&first.equals(((TwoTuple)obj).first)
&&second.equals(((TwoTuple)obj).second);
}
publicStringtoString(){
return"("+first+","+second+")";
}
}///:-
importjava.io.File;
importjava.io.FileNotFoundException;
importjava.util.LinkedList;
importjava.util.Scanner;
classMyPoint
{
publicbooleanvisited=false;
publicintparentRow=-1;
publicintparentColumn=-1;
publicfinalcharcontent;
publicintx;
publicinty;
publicMyPoint(charc,intx,inty)
{
this.content=c;
this.x=x;
this.y=y;
}
}
publicclassMaze
{
publicstaticMyPoint[][]getMazeArray(){
Scannerinput=null;
MyPoint[][]mazemap=newMyPoint[12][58];
try{
input=newScanner(newFile("Maze2tong.txt"));
introw=0;
while(input.hasNext()){
Stringline=input.nextLine();
for(intcolumn=0;column<=line.length()-1;column++){
charc=line.charAt(column);
MyPointpoint=newMyPoint(c,row,column);
mazemap[row][column]=point;
}
row++;
}
input.close();
}catch(FileNotFoundExceptione){
e.printStackTrace();
}
returnmazemap;
}
publicstaticbooleantomRun(MyPoint[][]maze,MyPointend)
{
intx=maze.length;
inty=maze[0].length;
LinkedList<MyPoint>stack=newLinkedList<MyPoint>();
for(inti=0;i<maze.length;i++){
for(intj=0;j<maze[i].length;j++){
if(maze[i][j].content=='S'){
stack.push(maze[i][j]);
maze[i][j].visited=true;
}
}
}
booleanresult=false;
while(!stack.isEmpty())
{
MyPointt=stack.pop();
//System.out.println("poppoint:"+t.x+""+t.y+"value:"+maze[t.x][t.y]);
if(t.content=='F')
{
result=true;
end.x=t.x;
end.y=t.y;
break;
}
if(t.x-1>0&&maze[t.x-1][t.y].visited==false&&maze[t.x-1][t.y].content!='W')
{
stack.push(maze[t.x-1][t.y]);
maze[t.x-1][t.y].parentRow=t.x;
maze[t.x-1][t.y].parentColumn=t.y;
maze[t.x-1][t.y].visited=true;
}
if(t.x+1<x&&maze[t.x+1][t.y].visited==false&&maze[t.x+1][t.y].content!='W')
{
stack.push(maze[t.x+1][t.y]);
maze[t.x+1][t.y].parentRow=t.x;
maze[t.x+1][t.y].parentColumn=t.y;
maze[t.x+1][t.y].visited=true;
}
if(t.y-1>0&&maze[t.x][t.y-1].visited==false&&maze[t.x][t.y-1].content!='W')
{
stack.push(maze[t.x][t.y-1]);
maze[t.x][t.y-1].parentRow=t.x;
maze[t.x][t.y-1].parentColumn=t.y;
maze[t.x][t.y-1].visited=true;
}
if(t.y+1<y&&maze[t.x][t.y+1].visited==false&&maze[t.x][t.y+1].content!='W')
{
stack.push(maze[t.x][t.y+1]);
maze[t.x][t.y+1].parentRow=t.x;
maze[t.x][t.y+1].parentColumn=t.y;
maze[t.x][t.y+1].visited=true;
}
}
returnresult;
}
publicstaticvoidshow(intx,inty,MyPoint[][]visited)
{
if(visited[x][y].parentRow==-1)
{
System.out.println("["+x+","+y+"]");
return;
}
show(visited[x][y].parentRow,visited[x][y].parentColumn,visited);
System.out.println("->"+"["+x+","+y+"]");
}
publicstaticvoidmain(String[]args)
{
MyPoint[][]maze=getMazeArray();
MyPointpoint=newMyPoint('c',1,1);
if(tomRun(maze,point))
{
System.out.println("逃生路径如下:");
show(point.x,point.y,maze);
}
else
System.out.println("无法走出迷宫!");
}
}
❺ 3道java编程题,求解
packageTestPerson;
/**
*(1)编写程序实现如下功能:已知Person类包含三个公共成员变量(姓名、性别、年龄)和一个构造方法,
*Student类是Person类的派生类,包含两个新的公共成员变量(学号、班号)、两个公共方法(修改年龄、显示基本信息)及一个构造方法。
*在测试类Test1中,定义一组学生对象,并初始化他们的基本信息,然后依次输出。
*/
publicclassTest1{
publicstaticvoidmain(String[]args){
Student[]student=newStudent[3];
student[0]=newStudent("小李","男",12,20181101,01);
student[1]=newStudent("小南","女",13,20001102,01);
student[2]=newStudent("小李","男",12,20181103,01);
for(Studentstu:student){
stu.showInformation();
}
}
}
classPerson{
publicStringname;
publicStringsex;
publicintage;
publicPerson(Stringname,Stringsex,intage){
super();
this.name=name;
this.sex=sex;
this.age=age;
}
}
classStudentextendsPerson{
publiclongstudentId;
publiclongclassId;
publicvoidsetAge(intage){
age=this.age;
}
publicvoidshowInformation(){
System.out.println("我的姓名是"+name+","+"我的性别是"+sex+","+"我的年龄是"+age
+"岁,"+"我的学号是"+studentId+","+"我的班号是"+classId+"班");
}
publicStudent(Stringname,Stringsex,intage,longstudentId,
longclassId){
super(name,sex,age);
this.studentId=studentId;
this.classId=classId;
}
}
不可否认,我现在是有点闲,所以我就帮你写第一个吧,至于后面两个,我就不写了,看看还有没有其他人有点闲时间,看缘分吧
运行结果:
我的姓名是小李,我的性别是男,我的年龄是12岁,我的学号是20181101,我的班号是1班
我的姓名是小南,我的性别是女,我的年龄是13岁,我的学号是20001102,我的班号是1班
我的姓名是小李,我的性别是男,我的年龄是12岁,我的学号是20181103,我的班号是1班