# How does this BST node-deletion algorithm work?

I'm trying to follow the BST algorithm in "Data Structures and Algorithms" by Granville Barnett, but I don't understand the node-deletion algorithm it describes below.

Section 3.3 (p. 22)

Removing a node from a BST is fairly straightforward, with four cases to consider:

1. the value to remove is a leaf node; or
2. the value to remove has a right subtree, but no left subtree; or
3. the value to remove has a left subtree, but no right subtree; or
4. the value to remove has both a left and right subtree in which case we promote the largest value in the left subtree.

Figure 3.2 (p. 22)

``````    23
/  \
14   31
/
7
\
9
``````
• Case #1 points to node 9.
• Case #2 points to node 7.
• Case #3 points to node 14.
• Case #4 points to node 23.

I interpret the text above for #4 to mean that when we remove 23, we promote 14 to root and make 31 its right child:

``````  14
/  \
7   31
\
9
``````

...but the book's algorithm (from p. 23) for case #4 bamboozles me (I've rewritten it here in Java):

``````1 boolean remove(T value) {
2   // ...
3
4   // case #4
5   Node largestValueNode = nodeToRemove.left;
6   while (largestValueNode.right != null) {
7       // find the largest value in the left subtree of nodeToRemove
8       largestValueNode = largestValueNode.right;
9   }
10
11  // delete the right child of largestValueNode's parent
12  findParent(largestValueNode.value).right = null;
13  nodeToRemove.value = largestValueNode.value;
14
15  count--;
16  return true; // successful
17}
``````

If I follow the algorithm, the `largestValueNode` is node 14, so its parent is node 23. Why does the algorithm nullify the right child of the parent?

Why does line 13 copy the `largestValueNode`'s value into the node to be deleted?

I would've expected lines 11-13 to be:

``````11  if (largestValueNode != null)
12      largestValueNode.right = nodeToRemove.right;
13  nodeToRemove.right = null;
``````

EDIT:

The book's algorithm indeed has a bug. The fix is below:

``````1 boolean remove(T value) {
2   // ...
3
4   // case #4
5   Node largestValueNode = nodeToRemove.left;
6   while (largestValueNode.right != null) {
7       // find the largest value in the left subtree of nodeToRemove
8       largestValueNode = largestValueNode.right;
9   }
10
11  Node p = findParent(largestValueNode.value);
12  if (p != null) {
13      if (nodeToRemove == p)
14          nodeToRemove.left = largestValueNode.left;
15      else
16          p.right = largestValueNode.left;
17  }
18  nodeToRemove.value = largestValueNode.value;
19
20  count--;
21  return true; // successful
22}
``````
-
Note - you're leaving off a critical line from the text you reference. Just before `count--`, the text has the following line: `nodeToRemove.Value = largestValueNode.Value`, which you're missing here. – Dan Nissenbaum Jul 8 '12 at 0:24
It's not missing. You might be looking at the end of the question, which is my own code that I was expecting the algorithm to be. The actual code from the book is right before my own. – user46874 Jul 8 '12 at 0:27
You're right - I was looking at the end of the question. Thanks for the correction. – Dan Nissenbaum Jul 8 '12 at 1:01

if you do this

``````11  if (largestValueNode != null)
12      largestValueNode.right = nodeToRemove.right;
13  nodeToRemove.right = null;
``````

you're not considering the case where `14` might have a right child. For example:

``````     23
/ \
14  31
/ \
7   15
\
9
``````

You're solution when removing `23` should be

``````     15
/ \
14  31
/
7
\
9
``````

So you're setting the right child of `15`'s original parent, `14` to null. This is what the first code is doing.

``````     23
/
14
/ \
7   15
\   \
9   31
``````

Also, the original code is also wrong; try something like this:

``````if(nodeToRemove == findParent(largestValueNode.value))
nodeToRemove.left = largestValueNode.left
else
findParent(largestValueNode.value).right = largestValueNode.left
nodeToRemove.value = largestValueNode.value
``````

Also to answer, "Why does line 13 copy the largestValueNode's value into the node to be deleted?"

We're deleting `largestValueNode`, before which we're storing it's value in the `nodeToRemove`

-
Lines 5-9 search for the largest node in the left subtree of the node to be removed. The largest node is identified by not having any right child. So if you had 15 in the tree, the `largestValueNode` would be 15 (which would have no right child). – user46874 Jul 8 '12 at 0:31
@user46874 edited the answer to clarify the point i was trying to make. Also, noted that the original code is also wrong. I've provided my solution. – deebee Jul 8 '12 at 0:55
Thanks, it makes sense now. Replacing lines 11-13 with your code fixes the problem. – user46874 Jul 8 '12 at 1:35
Good to know the original code is wrong - I've just spent a few hours on it and was thinking the whole time that I was missing something. There's an NPE problem too, and also no way to delete the root element. – Steve Feb 15 '14 at 21:39
Good to know the original code is wrong - I've just spent a few hours on it and was thinking the whole time that I was missing something. There's an NPE problem if the root element is passed, and anyway root element removal is not factored in. – Steve Feb 15 '14 at 21:49

Seems like the book's algorithm is wrong for this particular example (assuming you have translated to Java perfectly :)). It is doing what you have mentioned but it is right for the case:

where nodeToRemove = 23 and in your BST 14 had a right child 15. The book's algorithm would replace 23 with 15 here and set 14's right child to null. Your algorithm would fail in this case.

-
Note that the question left off a line of code from the text that was referenced, which resolves this issue. See comment beneath the question. – Dan Nissenbaum Jul 8 '12 at 0:25
... In fact, the line of code was not missing (see comments beneath question). – Dan Nissenbaum Jul 8 '12 at 1:01

Take a careful look at the line:

``````largestValueNode.right = nodeToRemove.right;
``````

Note how this line causes `14` to look like this (ignoring grandchildren):

``````  14
/  \
7   31
``````

But this is exactly what is desired! Since `14` now has `31` as its right child, it's no longer correct for `31` to be the right child of `15`, so for clean-up's sake, the right child of `15` is set to NULL.

-
The line you've quoted is my own code. I was expecting that to be in the algorithm suggested by the book. And there is no child `15`... – user46874 Jul 8 '12 at 0:28
You're right - I was unambiguously sloppy. I agree that the original code is incorrect. – Dan Nissenbaum Jul 8 '12 at 1:17

Good to know the original code is wrong - I've just spent a few hours on it and was thinking the whole time that I was missing something. There's an NPE problem if the root element is passed, and anyway root element removal is not factored in.

Here's my Java implementation that could probably use some optimization - suggestions welcome. `O (n log n)` worst case. Tests below.

``````public boolean remove(final T value0) {
BinarySearchTreeNode<T> target = findNode(value0);

// Node DNE
if (target == null) {
return false;
}

// Both children populated, no need for parent
if (target.right != null && target.left != null) {
BinarySearchTreeNode<T> max = maxChild(target.left);
findParent(max.value).right = null;
target.value = max.value;
}
// Root element targeted, parent DNE
else if (target == root) {
if (target.right == null && target.left == null) {
root = null;
}
else if (target.right == null) {
root = target.left;
}
else {
root = target.right;
}
}
// Non-root, single-child node - find if L or R child, update parent reference.
else {
BinarySearchTreeNode<T> parent = findParent(value0);

if (target.right == null && target.left != null) {
if (target.value.compareTo(parent.value) < 0) {
parent.left = target.left;
}
else {
parent.right = target.left;
}
}
else if (target.right != null && target.left == null) {
if (target.value.compareTo(parent.value) < 0) {
parent.left = target.right;
}
else {
parent.right = target.right;
}
}
}

return true;
}
``````

Unit tests (all pass, obviously):

``````package BinarySearchTreeTests;

import static org.junit.Assert.assertEquals;
import static org.junit.Assert.assertFalse;
import static org.junit.Assert.assertNull;
import static org.junit.Assert.assertTrue;

import org.junit.Before;
import org.junit.Test;

public class Remove {
BinarySearchTree<Integer> tree;

@Before
public void setUp() {
tree = new BinarySearchTree<Integer>();
}

@Test
public void fromEmptyTree() {
assertFalse(tree.remove(8));
}

@Test
public void fromTreeWithOnlyRootNode() {
assertTrue(tree.remove(10));
assertNull(tree.root);
}

@Test
public void nonexistentElement() {
assertFalse(tree.remove(8));
}

/**
*     N
* 10--|
*     |  6
*     5--|
*        3
*/
@Test
public void nodeWithNoRightChildren() {
tree.remove(10);
assertEquals(tree.root.value, Integer.valueOf(5));
assertEquals(tree.root.left.value, Integer.valueOf(3));
assertEquals(tree.root.right.value, Integer.valueOf(6));
}

/**
*         17
*     15--|
*     |   13
* 10--|
*     N
*/
@Test
public void nodeWithNoLeftChildren() {
tree.remove(10);
assertEquals(tree.root.value, Integer.valueOf(15));
assertEquals(tree.root.left.value, Integer.valueOf(13));
assertEquals(tree.root.right.value, Integer.valueOf(17));
}

/**
*           19
*        17-|
*        |  16
*     15-|
*     |  |  14
*     |  13-|
*     |     12
* 10--|
*     N
*/
@Test
public void nodeWithLeftAndRightChildren() {

tree.remove(15);
assertEquals(tree.root.right.value, Integer.valueOf(14));
assertNull(tree.root.right.left.right);
}

/**
*           18
*        15-|
*        |  [ALWAYS EMPTY]
*     15-|
*     |  |  13
*     |  12-|
*     |     11
* 10--|
*     N
*
@Test
public void removeDuplicate() {
Above diagram shows duplicate cases are already tested implicitly.
fail();
} */
}
``````
-