AVL tree rotation in java

I want to implement the Java AVL tree and to rotate the tree left and right. I am not getting this.

Can anybody by looking at the code below tell me how can I possibly rotate the tree left and right and then use fix up with those two functions to balance the AVL tree?

I hope someone here can guide me through this.

Thank you!

``````import java.util.Random;
import java.util.SortedSet;
import java.util.TreeSet;

public class AVLTree<T> extends
BinarySearchTree<AVLTree.Node<T>, T> implements SSet<T> {

Random rand;

public static class Node<T> extends BSTNode<Node<T>,T> {
int h;  // the height of the node
}

public AVLTree() {
sampleNode = new Node<T>();
rand = new Random();
c = new DefaultComparator<T>();
}

public int height(Node<T> u) {
return (u == null) ? 0 : u.h;
}

Node<T> u = new Node<T>();
u.x = x;
for (Node<T> w = u; w != nil; w = w.parent) {
// walk back up to the root adjusting heights
w.h = Math.max(height(w.left), height(w.right)) + 1;
}
fixup(u);
return true;
}
return false;
}

public void splice(Node<T> u) {
Node<T> w = u.parent;
super.splice(u);
for (Node<T> z = u; z != nil; z = z.parent)
z.h = Math.max(height(z.left), height(z.right)) +   1;
fixup(w);
}

public void checkHeights(Node<T> u) {
if (u == nil) return;
checkHeights(u.left);
checkHeights(u.right);
if (height(u) != 1 + Math.max(height(u.left), height(u.right)))
throw new RuntimeException("Check heights shows incorrect heights");
int dif = height(u.left) - height(u.right);
if (dif < -1 || dif > 1)
throw new RuntimeException("Check heights found height difference of " + dif);
}

/**
* TODO: finish writing this method
* @param u
*/
public void fixup(Node<T> u) {
while (u != nil) {
int dif = height(u.left) - height(u.right);
if (dif > 1) {
// TODO: add code here to fix AVL condition
// on the path from u to the root, if  necessary
} else if (dif < -1) {
// TODO: add code here to fix AVL condition
// on the path from u to the root, if necessary
}
u = u.parent;
}
}

public Node rotateLeft()
{
return rotateLeft(u.parent);
}

public void rotateLeft(Node<T> u) {
// TODO: Recompute height values at u and u.parent

}

public void rotateRight(Node<T> u) {
// TODO: Recompute height values at u and u.parent
}

public static <T> T find(SortedSet<T> ss, T x) {
SortedSet<T> ts = ss.tailSet(x);
if (!ts.isEmpty()) {
return ts.first();
}
return null;
}
/**
* This just does some very basic correctness testing
* @param args
*/
public static void main(String[] args) {
AVLTree<Integer> t = new AVLTree<Integer>();
Random r = new Random(0);
System.out.print("Running AVL tests...");
int n = 1000;
for (int i = 0; i < n; i++) {
t.checkHeights(t.r);
}
for (int i = 0; i < n; i++) {
t.remove(r.nextInt(2*n));
t.checkHeights(t.r);
}
System.out.println("done");

t.clear();
System.out.print("Running correctness tests...");
n = 100000;
SortedSet<Integer> ss = new TreeSet<Integer>();
Random rand = new Random();
for (int i = 0; i < n; i++) {
Integer x = rand.nextInt(2*n);
if (b1 != b2) {
throw new RuntimeException("Adding " + x + " gives " + b2                       + " in SortedSet and " + b1 + " in AVL Tree");
}
}
for (int i = 0; i < n; i++) {
Integer x = rand.nextInt(2*n);
Integer x1 = t.find(x);
Integer x2 = find(ss, x);
if (x1 != x2) {
throw new RuntimeException("Searching " + x + " gives " + x2
+ " in SortedSet and " + x1 + " in AVL Tree");
}
}
for (int i = 0; i < n; i++) {
Integer x = rand.nextInt(2*n);
boolean b1 = t.remove(x);
boolean b2 = ss.remove(x);
if (b1 != b2) {
throw new RuntimeException("Error (2): Removing " + x + " gives " + b2
+ " in SortedSet and " + b1 + " in AVL Tree");
}
}
for (int i = 0; i < n; i++) {
Integer x = rand.nextInt(2*n);
Integer x1 = t.find(x);
Integer x2 = find(ss, x);
if (x1 != x2) {
throw new RuntimeException("Error (3): Searching " + x + " gives " + x2
+ " in SortedSet and " + x1 + " in AVL Tree");
}
}
System.out.println("done");

}
}
``````
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Full AVL tree implementation:

``````public class AVLTree<T> {

private AVLNode<T> root;

private static class AVLNode<T> {

private T t;
private int height;
private AVLNode<T> left;
private AVLNode<T> right;

private AVLNode(T t) {
this.t = t;
height = 1;
}
}

public void insert(T value) {
root = insert(root, value);
}

private AVLNode<T> insert(AVLNode<T> n, T v) {
if (n == null) {
n = new AVLNode<T>(v);
return n;
} else {
int k = ((Comparable) n.t).compareTo(v);
if (k > 0) {
n.left = insert(n.left, v);
} else {
n.right = insert(n.right, v);
}
n.height = Math.max(height(n.left), height(n.right)) + 1;
int heightDiff = heightDiff(n);
if (heightDiff < -1) {
if (heightDiff(n.right) > 0) {
n.right = rightRotate(n.right);
return leftRotate(n);
} else {
return leftRotate(n);
}
} else if (heightDiff > 1) {
if (heightDiff(n.left) < 0) {
n.left = leftRotate(n.left);
return rightRotate(n);
} else {
return rightRotate(n);
}
} else;

}
return n;
}

private AVLNode<T> leftRotate(AVLNode<T> n) {
AVLNode<T> r = n.right;
n.right = r.left;
r.left = n;
n.height = Math.max(height(n.left), height(n.right)) + 1;
r.height = Math.max(height(r.left), height(r.right)) + 1;
return r;
}

private AVLNode<T> rightRotate(AVLNode<T> n) {
AVLNode<T> r = n.left;
n.left = r.right;
r.right = n;
n.height = Math.max(height(n.left), height(n.right)) + 1;
r.height = Math.max(height(r.left), height(r.right)) + 1;
return r;
}

private int heightDiff(AVLNode<T> a) {
if (a == null) {
return 0;
}
return height(a.left) - height(a.right);
}

private int height(AVLNode<T> a) {
if (a == null) {
return 0;
}
return a.height;
}

}
``````
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in order to rotate it right you need to first check if the parent is not root then if the parent is the right of the grand parent if so, set the right of the grand parent to the child else, set the left of the gran parent to the child

otherwise, root is child

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