递归的二分查找:
int BinarySearchRecursion(int array[], int findData, int start, int end) {
if (array == null || end <= 0)
return -1;
if (start > end)
return -1;
int mid = start + (end - start) / 2;
if (array[mid] == findData)
return mid;
else if (findData < array[mid])
return BinarySearchRecursion(array, findData, start, mid - 1);
else
return BinarySearchRecursion(array, findData, mid + 1, end);
}
把终止条件写在最前面总是更清晰,不然就要这么写:
int BinSearch(int Array[],int low,int high,int key/*要找的值*/)
{
if (low<=high)
{
int mid = (low+high)/2;
if(key == Array[mid])
return mid;
else if(key<Array[mid])
return BinSearch(Array,low,mid-1,key);
else if(key>Array[mid])
return BinSearch(Array,mid+1,high,key);
}
else
return -1;
}
以下摘自:http://www.cnblogs.com/yueyebigdata/p/5126333.html
很乱,不知道怎么排版的。先简单放着。
3. UnionFind并查集模板
import java.util.HashMap;
import java.util.HashSet;
class UnionFind {
HashMap<Integer, Integer> father = new HashMap();
// 初始化
UnionFind(HashSet<Integer> hashSet) {
for (Integer now : hashSet) {
father.put(now, now);
}
}
// O(n)复杂度的find
// public int find(int x) {
// int parent = father.get(x);
// while (parent != father.get(parent)) {
// parent = father.get(parent);
// }
// return parent;
// }
// O(1)复杂度的find
public int compressedFind(int x) {
int parent = father.get(x);
while (parent != father.get(parent)) {
parent = father.get(parent);
}
// 这里parent是他的最大祖先。那么,包括他以及中间的各种都直接设置为指道最大祖先。
int temp = -1;
int xFa = x;
while (xFa != father.get(xFa)) {
temp = father.get(xFa); // 因为要把xFa的祖先设置为最大祖先了,所以,得先把踏上一级father记录下来。
father.put(xFa, parent);
xFa = temp;
}
return parent;
}
// x,y有一条边。所以,如果他们的祖先不一样,那么就把他们随便谁和谁连起来
public void union(int x, int y) {
int xFa = compressedFind(x);
int yFa = compressedFind(y);
if (xFa != yFa) {
father.put(xFa, yFa);
}
}
}
2. 二分
非递归的,while-loop
public static int binarySearch(int[] nums, int target) {
if (nums == null || nums.length == 0) {
return -1;
}
int start = 0;
int end = nums.length - 1;
while (start <= end) {
int mid = start + (end - start) / 2;
if (nums[mid] == target) {
return mid;
} else if (nums[mid] < target) {
start = mid + 1;
} else {
end = mid - 1;
}
}
return -1;
}
递归的,recursion
public class Solution {
public static void main(String[] args) {
int[] a = {1, 2, 3, 4, 5};
System.out.println(binarySearch(a, 0, a.length-1, 6));
}
public static int binarySearch(int[] nums, int start, int end, int target) {
if (nums == null || nums.length == 0 || start > end) {
return -1;
}
int mid = start + (end - start) / 2;
if (nums[mid] == target) {
return mid;
} else if (nums[mid] > target) {
end = mid - 1;
} else {
start = mid + 1;
}
return binarySearch(nums, start, end, target);
}
}
1. 非递归的二叉树遍历:
前序遍历:一句话概括就是:先放进去root,然后放进去顶元素的right,然后放进去left。
public ArrayList<Integer> preorderTraversal(TreeNode root) {
// write your code here
ArrayList<Integer> result = new ArrayList<Integer>();
Stack<TreeNode> stack = new Stack<TreeNode>();
if (null == root) {
return result;
}
stack.push(root);
while (!stack.empty()) {
TreeNode cur = stack.pop();
result.add(cur.val);
if (cur.right != null) {
stack.push(cur.right);
}
if (cur.left != null) {
stack.push(cur.left);
}
}
中序遍历:一句话总结概括:在进入while循环之前什么都不错,先把cur=root。进去之后,首先再用一个wihle一直往左走知道尽头,也一路的存入stack,然后把顶元素存入result,并且这时候把cur变成顶元素的右儿子。
public ArrayList<Integer> inorderTraversal(TreeNode root) {
// write your code here
ArrayList<Integer> result = new ArrayList<Integer>();
Stack<TreeNode> stack = new Stack<TreeNode>();
if (null == root) {
return result;
}
TreeNode cur = root;
while (cur != null || !stack.empty()) {
while (cur != null) {
stack.push(cur);
cur = cur.left;
}
cur = stack.pop();
result.add(cur.val);
cur = cur.right;
}
return result;
}
后序遍历:一句话总结,首先用一个cur,和一个pre。进入之前把root存进去。然后,只要是上一个处理的是null,或者是pre.left,pre.right等于现在的cur,就先把left存进去,如果left空,存进去right。然后,如果上一次处理的是当前结点的left,那么说明该处理右边了,所以把right存进去,如果以上两个情况都不是,那么就要存结果了,并且pop。记住就是最后的时候pre = cur。
public ArrayList<Integer> postorderTraversal(TreeNode root) {
// write your code here
ArrayList<Integer> result = new ArrayList<Integer>();
Stack<TreeNode> stack = new Stack<TreeNode>();
if (null == root) {
return result;
}
stack.push(root);
TreeNode pre = null;
TreeNode cur = root;
while (!stack.empty()) {
cur = stack.peek();
if (pre == null || pre.left == cur || pre.right == cur) {
if (cur.left != null) {
stack.push(cur.left);
} else if (cur.right != null) {
stack.push(cur.right);
}
} else if (cur.left == pre) {
if (cur.right != null) {
stack.push(cur.right);
}
} else {
result.add(cur.val);
stack.pop();
}
pre = cur;
}
return result;
}
0. 下面一大堆大杂烩。
6移位操作
“>> 右移,高位补符号位” 这里右移一位表示除2
“>>> 无符号右移,高位补0”; 与>>类似
“<< 左移” 左移一位表示乘2,二位就表示4,就是2的n次方
6树的各种操作
import java.util.ArrayDeque;
import java.util.Queue;
public class Solution{
public static void main(String[] args){
TreeNode root = new TreeNode(1);
root.left = new TreeNode(2);
root.right = new TreeNode(3);
root.left.left = null;
root.left.right =null;
root.right.left = null;
root.right.right =null;
levelOrder(root);
}
//树的遍历
//先序遍历
public static void preOrder(TreeNode root){
if(root == null) return;
System.out.println(root.val);
preOrder(root.left);
preOrder(root.right);
}
//层次遍历
public static void levelOrder(TreeNode root){
Queue<TreeNode> q = new ArrayDeque<TreeNode>();
q.add(root);
while( !q.isEmpty()){
TreeNode tmp = q.poll();
System.out.println(tmp.val);
if(tmp.left != null ) q.add(tmp.left);
if(tmp.right != null ) q.add(tmp.right);
}
}
//树的高度
public static int treeHeight(TreeNode root){
int high = 0;
if(root == null) return 0;
high = 1 + Math.max(treeHeight(root.left), treeHeight(root.right));
return high;
}
//二叉排序树
public static boolean isBST(TreeNode root, int left, int right){
if(root == null) return true;
return (left < root.val && root.val < right && isBST(root.left,left ,root.val) && isBST(root.right,root.val,right));
}
public static boolean isBST(TreeNode root){
return isBST(root,Integer.MIN_VALUE, Integer.MAX_VALUE);
}
}
class TreeNode{
TreeNode left;
TreeNode right;
int val;
TreeNode(int x){
val = x;
}
}
5快速排序
public static void qSort(int[] a, int low, int high){
if(low >= high) return;
int first = low, last = high, key = a[first];
while(first < last){
while(first < last && a[last] >= key) --last;
a[first] = a[last];
while(first < last && a[first] <= key) ++first;
a[last] = a[first];
}
a[first] = key;
qSort(a, low, first - 1);
qSort(a, last + 1, high);
}
4归并排序(背下来)。
public static void mergeSort(int[] a, int[] temp, int left, int right){
if(left >= right) return;
int mid = (left + right) / 2;
mergeSort(a, temp, left, mid);
mergeSort(a, temp, mid+1, right);
int p_final = left, p_left = left, p_right = mid + 1;
while(p_left <= mid || p_right <= right){
if(p_left <= mid && (p_right >right || a[p_left] <= a[p_right])){
temp[p_final++] = a[p_left++];
}
else{
temp[p_final++] = a[p_right++];
}
}
for ( int i = left; i <= right; i++){
a[i] = temp[i];
}
}
3. 二分函数(背下来)。
public static int binSearch(int[] a, int key){
int left = 0;
int right = a.length - 1;
while(left <= right){
int mid = (left + right) / 2;
if(key < a[mid]){
right = mid -1;
}
else if (key > a[mid]){
left = mid + 1;
}
else{
return mid;
}
}
return -1;
}
1. java的swap函数。交换
public static void swap ( int [] data, int a, int b) {
int t = data [a];
data [a] = data [b];
data [b] = t;
}
2. 数组翻转函数(reverse)
2.向右移动数组k位(rotate array);
public class Solution {
public void rotate(int[] nums, int k) {
if(nums.length <= 1){
return;
}
//step each time to move
int step = k % nums.length;
reverse(nums,0,nums.length - 1);//放到最后就是向左移
reverse(nums,step,nums.length - 1);
reverse(nums,0,step - 1);
}
//reverse int array from n to m
public void reverse(int[] nums, int n, int m){
while(n < m){
nums[n] ^= nums[m];
nums[m] ^= nums[n];
nums[n] ^= nums[m];
n++;
m--;
}
}
}
3. 字符串转成字符数组
s.toCharArray();
方法1:直接在构造String时转换。
char[] data = {'a', 'b', 'c'};
String str = new String(data);
方法2:调用String类的方法转换。
String.valueOf(char[] ch)
4.字符串翻转(String reverse)
new String
整数数组转化成字符串
Arrays.toString(a)
补充:我曾写过的快速排序和冒泡排序
quicksort
43125第一次循环后是23145, 4是pivot,4左边的都比它小,右边的都比它大。注意一定是j先往左走,不然结果不对。
public class Qksort{
public static void sort(int array[] , int low , int high ){
int i = low , j = high , index = array[i];
if(low >= high )return ;
while (i<j)
{
while(i<j && array[j]>= index)
j-- ;
if(i< j )
array[i++] = array[j];
while(i<j && array[i]<= index)
i++ ;
if(i<j )
array[j--] = array[i];
}
array[i]= index ;
sort(array, low , i - 1);
sort(array, i + 1 , high );
}
public static void main(String args[]){
int a[] = {4,3,1,2,5};
sort(a, 0 , a.length - 1);
for(int i = 0 ; i < a.length ; i++)
System.out.println(a[i]);
}
}
bubblesort
public class BBsort{
private static void BBsort(int array[])
{
int temp ;
int len = array.length;
for(int i = 0 ; i < len-1 ; i++)
{
for(int j = 0 ; j < len - i - 1 ; j ++ )
{
if(array[j]>array[j+1])
{
temp = array[j];
array[j] = array[j+1];
array[j+1] = temp ;
}
}
}
}
public static void main(String args[])
{
int a[] = {4,3,1,5,6,1,2,4,8};
BBsort(a);
for(int i = 1 ; i < a.length ; i ++ )
System.out.println(a[i]);
}
}
另:
https://github.com/Yuelinghui/personNote/blob/master/10大基础实用算法.md