JavaAlgorithms/DataStructures/Trees/AVLSimple

  
package DataStructures.Trees;

/*
* Avl is algo that balance itself while adding new alues to tree
* by rotating branches of binary tree and make itself Binary seaarch tree
* there are four cases which has to tackle 
* rotating - left right ,left left,right right,right left 

Test Case:

AVLTree tree=new AVLTree();
		tree.insert(20);
		tree.insert(25);
		tree.insert(30);
		tree.insert(10);
		tree.insert(5);
		tree.insert(15);
		tree.insert(27);
		tree.insert(19);
		tree.insert(16);
		
		tree.display();


*/


public class AVLTree {
	private class Node{
		int data;
		int height;
		Node left;
		Node right;
		Node(int data){
			this.data=data;
			this.height=1;
		}
		
	}
	private Node root;
	public void insert(int data) {
		this.root=insert(this.root,data);
	}
	private Node insert(Node node,int item) {
		if(node==null) {
			Node add=new Node(item);
			return add;
		}
		if(node.data>item) {
			node.left=insert(node.left,item);
		}
		if(node.data<item) {
			node.right=insert(node.right,item);
		}
		node.height=Math.max(height(node.left),height(node.right))+1;
		int bf=bf(node);
		//LL case
		if(bf>1&&item<node.left.data)
			return rightRotate(node);
		//RR case
		if(bf<-1&&item>node.right.data)
			return leftRotate(node);
		//RL case
		if(bf<-1&&item<node.right.data) {
			node.right=rightRotate(node.right);
			return leftRotate(node);
		}
		//LR case
		if(bf>1&&item>node.left.data) {
			node.left=leftRotate(node.left);
			return rightRotate(node);
		}
			
		return node;
	}
	public void display() { 
		this.display(this.root);
		System.out.println(this.root.height);
	}
	private void display (Node node) {
		String str="";
		if(node.left!=null)
			str+=node.left.data+"=>";
		else
			str+="END=>";
		str+=node.data+"";
		if(node.right!=null)
			str+="<="+node.right.data;
		else
			str+="<=END";
		System.out.println(str);
		if(node.left!=null)
			display(node.left);
		if(node.right!=null)
			display(node.right);
	}
	private int height(Node node) {
		if(node==null) {
			return 0;
		}
		return node.height;
		
	}
	private int bf(Node node) {
		if(node==null)
			return 0;
		return height(node.left)-height(node.right);
	}
	
	private Node rightRotate(Node c) {
		Node b=c.left;
		Node T3=b.right;
		
		b.right=c;
		c.left=T3;
		c.height=Math.max(height(c.left),height(c.right))+1;
		b.height=Math.max(height(b.left),height(b.right))+1;
		return b;
		
	}
	private Node leftRotate(Node c) {
		Node b=c.right;
		Node T3=b.left;
		
		b.left=c;
		c.right=T3;
		c.height=Math.max(height(c.left),height(c.right))+1;
		b.height=Math.max(height(b.left),height(b.right))+1;
		return b;
		
	}

}
Update AVLSimple 2020-05-25 05:36:36 +08:00
			`package DataStructures.Trees;`

			`/*`
			`* Avl is algo that balance itself while adding new alues to tree`
			`* by rotating branches of binary tree and make itself Binary seaarch tree`
			`* there are four cases which has to tackle`
			`* rotating - left right ,left left,right right,right left`

			`Test Case:`

			`AVLTree tree=new AVLTree();`
			`tree.insert(20);`
			`tree.insert(25);`
			`tree.insert(30);`
			`tree.insert(10);`
			`tree.insert(5);`
			`tree.insert(15);`
			`tree.insert(27);`
			`tree.insert(19);`
			`tree.insert(16);`

			`tree.display();`




			`*/`



Create AVLSimple 2020-05-23 08:03:40 +08:00			`public class AVLTree {`
			`private class Node{`
			`int data;`
			`int height;`
			`Node left;`
			`Node right;`
			`Node(int data){`
			`this.data=data;`
			`this.height=1;`
			`}`

			`}`
			`private Node root;`
			`public void insert(int data) {`
			`this.root=insert(this.root,data);`
			`}`
			`private Node insert(Node node,int item) {`
			`if(node==null) {`
			`Node add=new Node(item);`
			`return add;`
			`}`
			`if(node.data>item) {`
			`node.left=insert(node.left,item);`
			`}`
			`if(node.data<item) {`
			`node.right=insert(node.right,item);`
			`}`
			`node.height=Math.max(height(node.left),height(node.right))+1;`
			`int bf=bf(node);`
			`//LL case`
			`if(bf>1&&item<node.left.data)`
			`return rightRotate(node);`
			`//RR case`
			`if(bf<-1&&item>node.right.data)`
			`return leftRotate(node);`
			`//RL case`
			`if(bf<-1&&item<node.right.data) {`
			`node.right=rightRotate(node.right);`
			`return leftRotate(node);`
			`}`
			`//LR case`
			`if(bf>1&&item>node.left.data) {`
			`node.left=leftRotate(node.left);`
			`return rightRotate(node);`
			`}`

			`return node;`
			`}`
			`public void display() {`
			`this.display(this.root);`
			`System.out.println(this.root.height);`
			`}`
			`private void display (Node node) {`
			`String str="";`
			`if(node.left!=null)`
			`str+=node.left.data+"=>";`
			`else`
			`str+="END=>";`
			`str+=node.data+"";`
			`if(node.right!=null)`
			`str+="<="+node.right.data;`
			`else`
			`str+="<=END";`
			`System.out.println(str);`
			`if(node.left!=null)`
			`display(node.left);`
			`if(node.right!=null)`
			`display(node.right);`
			`}`
			`private int height(Node node) {`
			`if(node==null) {`
			`return 0;`
			`}`
			`return node.height;`

			`}`
			`private int bf(Node node) {`
			`if(node==null)`
			`return 0;`
			`return height(node.left)-height(node.right);`
			`}`

			`private Node rightRotate(Node c) {`
			`Node b=c.left;`
			`Node T3=b.right;`

			`b.right=c;`
			`c.left=T3;`
			`c.height=Math.max(height(c.left),height(c.right))+1;`
			`b.height=Math.max(height(b.left),height(b.right))+1;`
			`return b;`

			`}`
			`private Node leftRotate(Node c) {`
			`Node b=c.right;`
			`Node T3=b.left;`

			`b.left=c;`
			`c.right=T3;`
			`c.height=Math.max(height(c.left),height(c.right))+1;`
			`b.height=Math.max(height(b.left),height(b.right))+1;`
			`return b;`

			`}`

			`}`