import java.util.ArrayList;
import java.util.Arrays;
import java.util.List;
/**
* Source : https://oj.leetcode.com/problems/convert-sorted-list-to-binary-search-tree/
*
*
* Given a singly linked list where elements are sorted in ascending order,
* convert it to a height balanced BST.
*/
public class ConvertSortedList {
/**
* 将一个有序链表转化为一棵AVL树
* 可以先把单向链表转化为有序数组,然后将数组转化为AVL树
* 或者使用双指针,快指针每次移动两个位置,慢指针每次移动一个位置,这样就能找到中间的节点
*
* 还有一种方法:
* 找到链表总个数total,一次递归如下:
* 递归查找左子树,每次递归的时候将head指向下一个节点
* 左子树递归完成之后,head指向了mid节点
* 构造root节点,当前head指向的就是mid节点,也就是root节点
* 递归构造右子树
* 构造根节点,并返回
*
* @param head
* @return
*/
public TreeNode convert (ListNode head) {
ListNode node = head;
int total = 0;
while (node != null) {
total++;
node = node.next;
}
return convert(new HeadHolder(head), 0, total-1);
}
/**
* 因为每次递归需要改变head的值,所以使用一个HeadHolder指向head,每次修改headHolder的指向
*
* @param head
* @param left
* @param right
* @return
*/
public TreeNode convert (HeadHolder head, int left, int right) {
if (left > right) {
return null;
}
int mid = (left + right) / 2;
TreeNode leftChild = convert(head, left, mid-1);
// 上面递归完成之后,head指向了mid位置的节点
TreeNode root = new TreeNode(head.head.value);
// head的下一个节点就是右子树的第一个节点
head.head = head.head.next;
TreeNode rightChild = convert(head, mid+1, right);
root.leftChild = leftChild;
root.rightChild = rightChild;
return root;
}
private class HeadHolder {
ListNode head;
public HeadHolder(ListNode head) {
this.head = head;
}
}
public ListNode createList (int[] arr) {
if (arr.length == 0) {
return null;
}
ListNode head = new ListNode();
head.value = arr[0];
ListNode pointer = head;
for (int i = 1; i < arr.length; i++) {
ListNode node = new ListNode();
node.value = arr[i];
pointer.next = node;
pointer = pointer.next;
}
return head;
}
public void binarySearchTreeToArray (TreeNode root, List<Character> chs) {
if (root == null) {
chs.add('#');
return;
}
List<TreeNode> list = new ArrayList<TreeNode>();
int head = 0;
int tail = 0;
list.add(root);
chs.add((char) (root.value + '0'));
tail ++;
TreeNode temp = null;
while (head < tail) {
temp = list.get(head);
if (temp.leftChild != null) {
list.add(temp.leftChild);
chs.add((char) (temp.leftChild.value + '0'));
tail ++;
} else {
chs.add('#');
}
if (temp.rightChild != null) {
list.add(temp.rightChild);
chs.add((char)(temp.rightChild.value + '0'));
tail ++;
} else {
chs.add('#');
}
head ++;
}
//去除最后不必要的
for (int i = chs.size()-1; i > 0; i--) {
if (chs.get(i) != '#') {
break;
}
chs.remove(i);
}
}
private class TreeNode {
TreeNode leftChild;
TreeNode rightChild;
int value;
public TreeNode(int value) {
this.value = value;
}
public TreeNode() {
}
}
private class ListNode {
ListNode next;
int value;
public ListNode(int value) {
this.value = value;
}
public ListNode() {
}
}
public static void main(String[] args) {
ConvertSortedList convertSortedList = new ConvertSortedList();
int[] arr = new int[]{1,2,3,4,5,6};
List<Character> chs = new ArrayList<Character>();
TreeNode root = convertSortedList.convert(convertSortedList.createList(arr));
convertSortedList.binarySearchTreeToArray(root, chs);
System.out.println(Arrays.toString(chs.toArray(new Character[chs.size()])));
}
}