# AVL Tree in C++ - Stack Overflow Exception

I'm writing an AVL tree program in C++. I'm basing it off of a BST Priority Queue program I previously made. Unfortunately every time a new node is added that should cause a rotation, a stack overflow exception is thrown.

Here's my code thus far:

node.h

``````#ifndef NODE_H_
#define NODE_H_

#include "stdio.h"
#include <iostream>
using namespace std;

class node
{
public:node(int inputValue)
{
value = inputValue;
Right = NULL;
Left = NULL;
Parent = NULL;
}

node* Right;
node* Left;
node* Parent;
int value;
int Priority;

int AvlValue;
void UpdateHeight();

private:int Height(node* root);
};

void node::UpdateHeight()
{
int Right = Height(this->Right);
int Left = Height(this->Left);
if (Right == -1)
Right = 0;
if (Left == -1)
Left = 0;

AvlValue = Left - Right;
}

int node::Height(node* root)
{
if (root == NULL) return -1;
return max(Height(root->Left), Height(root->Right)) + 1;
}
#endif
``````

AVL.h

``````#ifndef AVL_H_
#define AVL_H_

#include "node.h"
#include <string>
#include <iostream>
using namespace std;

class AVL
{
private:
int size;
public:
AVL(void);
~AVL(void);

int Peek();
int RemoveAndDisplay();
int Height(node* root);
int SearchFor(int Priority);

void Controller();

void PreOrder(node* root);
void inorder(node* root);

void Traverse(node* root);
node* First();
void LevelOut();

node* LRotation(node* current);
node* RRotation(node* current);
node* DoubleRotationLR(node* current);
node* DoubleRotationRL(node* current);
};

AVL::AVL()
{
size = 0;
}

AVL::~AVL()
{
}

void AVL::LevelOut()
{

node* sort;
while(current->Left != NULL || current->Right != NULL)
{
if(current->AvlValue != 2 && current->AvlValue != -2)
{
if(current->Left != NULL)
{
current = current->Left;
}
else if(current->Right != NULL)
{
current = current->Right;
}
}
else
{
sort = current;
if (sort->AvlValue == 2)
{
if (sort->Left->AvlValue == 1)
{
RRotation(sort);
}
else if(sort->Left->AvlValue == -1)
{
DoubleRotationLR(sort);
}
}
else
{
if (sort->Right->AvlValue == -1)
{
LRotation(sort);
}
else if(sort->Right->AvlValue == 1)
{
DoubleRotationRL(sort);
}
}
}
}
}

node* AVL::LRotation(node* current)
{
node* RightChild = current->Right;
current->Parent = RightChild;
RightChild->Left = current;

return RightChild;
}

node* AVL::RRotation(node* current)
{
node* LeftChild = current->Left;
current->Parent = LeftChild;
LeftChild->Right = current;

return LeftChild;
}

node* AVL::DoubleRotationLR(node* current)
{
node* tmp = current;
tmp->Left = LRotation(tmp->Left);
tmp = RRotation(tmp);
return tmp;
}

node* AVL::DoubleRotationRL(node* current)
{
node* tmp = current;
tmp->Right = RRotation(tmp->Right);
tmp = LRotation(tmp);
return tmp;
}

int AVL::Peek()
{
while(current->Left != NULL)
{
current = current->Left;
}
return current->value;
}

int AVL::RemoveAndDisplay()
{
int valueReturn = -1;
node* deleterPointer;

if(current->Left != NULL)
{
while(current->Left != NULL)
{
current = current->Left;
}
valueReturn = current->value;

deleterPointer = current->Parent;
delete current;
deleterPointer->Left = NULL;
}
else
{
valueReturn = current->value;
current = current->Right;
}
size--;
LevelOut();
return valueReturn;
}

int AVL::SearchFor(int sPriority)
{
bool keepGoing = true;
int valueToReturn = -1;

while(keepGoing)
{
if(current->Priority == sPriority)
{
valueToReturn = current->value;
keepGoing = false;
}
else
{
if(current->Priority > sPriority && current->Left != NULL)
{
current = current->Left;
keepGoing = true;
}
else if(current->Priority < sPriority && current->Right != NULL)
{
current = current->Right;
keepGoing = true;
}
else
{
keepGoing = false;
}
}
}
return valueToReturn;
}

{
bool nextLvL = true;
{
}
else
{
while(nextLvL)
{
if(current->Priority > nPriority)
{
if(current->Left != NULL)
{
current = current->Left;
nextLvL = true;
}
else
{
current->Left = new node(nvalue);
current->Left->Priority = nPriority;
current->Left->Parent = current;
nextLvL = false;
}
}
else
{
if (current->Right != NULL)
{
current = current->Right;
nextLvL = true;
}
else
{
current->Right = new node(nvalue);
current->Right->Priority = nPriority;
current->Right->Parent = current;
nextLvL = false;
}
}
}
}
size++;
LevelOut();
}

{
int inputvalue = 0;
cout << "\t Main Menu " << endl;
cout << "   1. Add " << endl;
cout << "   2. Remove " << endl;
cout << "   3. Peek " << endl;
cout << "   4. SearchFor " << endl;
cout << "   5. Size " << endl;
cout << "   6. Inorder " << endl;
cout << "   7. PreOrder " << endl;
cout << "   8. Height " << endl;
cout << "   0. Quit " << endl;

cout << "  Input: ";
cin>>inputvalue;
return inputvalue;
}

{
int userInput = -1;
int prior;
int SearchForValue = -1;

switch(indicator)
{
case 1:
cout << "Value to add: ";
cin>> userInput;
cout << "Priority for input: ";
cin>> prior;
break;
case 2:
cout << "Item Removed: " << RemoveAndDisplay() << endl;
break;
case 3:
cout << "The first item in the Queue has a value of: " << Peek() << endl;
break;
case 4:
cout << "Priority to Search for: ";
cin>> prior;
SearchForValue = SearchFor(prior);
break;
case 5:
cout << "Total items in the Queue is: " << size << endl;
break;
case 6:
cout << "First Value: " << First()->value << endl;
printf("\n");
break;
case 7:
printf("\n");
break;
case 8:
break;
case 0:
cout << "\tGood Bye!" << endl;
break;
default:
break;
}

}

node* AVL::First()
{
while(current->Left != NULL)
current = current->Left;
return current;
}

void AVL::Traverse(node* root)
{
if (root != NULL)
{
root->UpdateHeight();
Traverse(root->Left);
Traverse(root->Right);
}
}

void AVL::PreOrder(node* root)
{
if(root != NULL){
cout << root->value << ", ";
PreOrder(root->Left);
PreOrder(root->Right);
}
}

void AVL::inorder(node* root)
{
if(root != NULL){
inorder(root->Left);
cout << root->value << ", ";
inorder(root->Right);
}
}

int AVL::Height(node* root)
{
if (root == NULL) return -1;
return max(Height(root->Left), Height(root->Right)) + 1;
}

void AVL::Controller()
{
int input = -1;
while(input != 0)
{
}
}

#endif
``````

AVL.cpp

``````#include "AVL.h"

int main()
{
AVL avl;
avl.Controller();
return 0;
}
``````
-
What's the stack trace when the stack overflow occurs? –  Ben Voigt May 18 '12 at 4:31
I just went through the call stack and it looks like it's breaking on line 45 of node.h int node::Height(node* root) { if (root == NULL) return -1; return max(Height(root->Left), Height(root->Right)) + 1; } –  o_man May 18 '12 at 4:54

Seems like a logic error - after some `printf`-debugging it appears that sometimes a node that is known as `root->Left` will still have `root` as its `Right` member. Therefore calling `Height(root->Left)` will eventually attempt to `Height(root->Left->Right)` and run into `root` again.

(Also, `Height()` should be declared static since it doesn't use `this` in any way.)

-
That sounds about right. I've been running some tests, and it looks like a 3 node rotation works fine, but after that it breaks. Any suggestions on how to patch this up? –  o_man May 18 '12 at 5:58
I'm not sure, haven't had time to look at this too deeply yet, but azhrei's answer might help. –  DCoder May 18 '12 at 6:31
Do you really want to ignore the return values of the Rotation functions called by `LevelOut`?
For example, `AVL::LevelOut` calls: `RRotation(sort)`
Which declared: `node* AVL::RRotation(node* current)`