When deleting a node with two children, you can either choose its in-order successor node or its in-order predecessor node. In this case it's finding the the largest value in the left sub-tree (meaning the right-most child of its left sub-tree), which means that it is finding the node's in-order predecessor node.

Once you find the replacement node, you don't actually *delete* the node to be deleted. Instead you take the value from the successor node and store that value in the node you want to delete. Then, you delete the successor node. In doing so you preserve the binary search-tree property since you can be sure that the node you selected will have a value that is lower than the values of all the children in the original node's left sub-tree, and greater that than the values of all the children in the original node's right sub-tree.

**EDIT**

After reading your question a little more, I think I have found the problem.

Typically what you have in addition to the `delete`

function is a `replace`

function that replaces the node in question. I think you need to change this line of code:

```
FindParent(largestValue).Right <- 0
```

to:

```
FindParent(largestValue).Right <- largestValue.Left
```

If the `largestValue`

node doesn't have a left child, you simply get `null`

or `0`

. If it does have a left child, that child becomes a replacement for the `largestValue`

node. So you're right; the code doesn't take into account the scenario that the `largestValue`

node might have a left child.

**Another EDIT**

Since you've only posted a snippet, I'm not sure what the context of the code is. But the snippet as posted does seem to have the problem you suggest (replacing the wrong node). Usually, there are three cases, but I notice that the comment in your snippet says `//Case 4`

(so maybe there is some other context).

Earlier, I alluded to the fact that `delete`

usually comes with a `replace`

. So if you find the `largestValue`

node, you delete it according to the two simple cases (node with no children, and node with one child). So if you're looking at pseudo-code to delete a node with two children, this is what you'll do:

```
get largestValue from nodeToRemove.Left
nodeToRemove.Value <- largestValue.Value
//now replace largestValue with largestValue.Left
if largestValue = largestValue.Parent.Left then
largestValue.Parent.Left <- largestValue.Left //is largestValue a left child?
else //largestValue must be a right child
largestValue.Parent.Right <- largestValue.Left
if largestValue.Left is not null then
largestValue.Left.Parent <- largestValue.Parent
```

I find it strange that a Data Structures And Algorithms book would leave out this part, so I am inclined to think that the book has further split up the deletion into a few more cases (since there are three standard cases) to make it easier to understand.

To prove that the above code works, consider the following tree:

```
8
/ \
7 9
```

Let's say that you want to delete `8`

. You try to find `largestValue`

from `nodeToRemove.Left`

. This gives you `7`

since the left sub-tree only has one child.

Then you do:

```
nodeToRemove.Value <- largestValue.Value
```

Which means:

```
8.value <- 7.Value
```

or

```
8.Value <- 7
```

So now your tree looks like this:

```
7
/ \
7 9
```

You need to get rid of the replacement node and so you're going to replace `largestValue`

with `largestValue.Left`

(which is `null`

). So first you find out what kind of child `7`

is:

```
if largestValue = largestValue.Parent.Left then
```

Which means:

```
if 7 = 7.Parent.Left then
```

or:

```
if 7 = 8.Left then
```

Since `7`

is `8`

's left child, need to replace `8.Left`

with `7.Right`

(`largestValue.Parent.Left <- largestValue.Left`

). Since `7`

has no children, `7.Left`

is null. So `largestValue.Parent.Left`

gets assigned to null (which effectively removes its left child). So this means that you end up with the following tree:

```
7
\
9
```

`largetstValue`

, probably they expect removing (by garbage collector) when the only pointer to that node (`Right`

link from parent of that node) is reseted to`0`

. – ony Jul 4 '10 at 9:02