There is a problem with how root
is moved to point to a new location. If there are doubts about that, consider the following two statements. Note that the variable naming convention from the original code above is used for consistency.
*root = b; // (1)
root = &b; // (2)
In (1)
, the contents of the root pointer are modified to contain the value stored in the b
variable. The address of root
has not been modified in any way. The address root
has prior to (1)
executing remains unchanged after (1)
is finished.
In (2)
, root
is now pointing to the address of the b
variable. Because the address where root
is pointing has been modified, the contents of the root
pointer now equal the value in the b
variable.
I strongly recommend stepping through the void AVLTree::RotateLeft(Node *root)
function line by line and inspecting all variables' addresses and contents to see this first hand. I have performed a simulation of the above actions on sample integer data and pointers moved around as expected using (2)
.
Before the rotation occurs on the sample data, it is expected that the unbalanced tree should be arranged such that the 3
node is pointed to by root
. Then root->right
points to 5
, and the root->right->right
points to 10
. The root->right->left
should be nullptr
, and the root->left
should also be nullptr
.
If this not the case, then either the AVL insertion algorithm is implemented incorrectly or the design requirements are different than expected (e.g. AVL tree on Wikipedia, Data Structures and Algorithm Analysis in C++ (3rd Edition) [Hardcover] by Mark Allen Weiss, AVL Tree Tutorial on Eternally Confuzzled by Julienne Walker).
Regarding the movement of balancing the tree, where the end result is root
points to 5
, the root->left
points to 3
and root->right
points to 10
, the right pointer of the passed in root
pointer will be set to point to the left pointer of the local pB
pointer (see below), the left pointer of pB
will point to the passed in root
pointer, and root
will be set to point to the local variable pB
(originally set to the root->right
pointer in this case).
Using the sample data above, the body of the function is modified. Note that this is not consistent with how GetRight()
and GetLeft()
appear to return a Node copy in the original post above. The modified function body below is consistent with the single AVL rotation with right child
implemented by Mark Allen Weiss referenced above. Since the original post does not have a height variable, the code below does not either.
//
// The `root` variable is passed as a pointer by reference
//
void AVLTree::RotateLeft(Node* & root)
{
//
// This works as long as the GetRight() method returns a pointer, not a Node copy
//
Node *pB = root->GetRight();
//
// In the example values for three nodes, the root->right will become nullptr
//
root->SetRight(pB->GetLeft());
//
// In the example values, the pB->left will point to the node with value of 3
//
pB->SetLeft(root);
//
// Move root to point to where pB does (root->right)
//
root = pB;
}
nullptr
. For more details: What exactly is nullptr?. If not, then it is much better to use theNULL
macro. It is highly likely comparing pointers to zero will cost points.b.SetLeft(a)
, not&a
.SetLeft
takes aNode
, not aNode*
. If possible, you should also exchange allNode*
forNode&
in your program, because you are using pointers as if they were references...nullptr
tip