Write the implementation of the function `ComputeMedian`

that computes the median value in the tree in `O(n)`

time. Assume that the tree is a BST but is not necessarily balanced.
Recall that the median of n numbers is defined as follows:
If n is odd, the median is x such that the number of values smaller than x is equal to the number of values greater than x. If n is even, then one plus the number of values smaller than x is equal to the number of values greater than x. For example, given the numbers
8, 7, 2, 5, 9, the median is 7, because there are two values smaller than 7 and two values larger than 7. If we add number 3 to the set, the median becomes 5.

Here is the class of binary search tree node:

```
template <class T>
class BSTNode
{
public:
BSTNode(T& val, BSTNode* left, BSTNode* right);
~BSTNode();
T GetVal();
BSTNode* GetLeft();
BSTNode* GetRight();
private:
T val;
BSTNode* left;
BSTNode* right;
BSTNode* parent; //ONLY INSERT IS READY TO UPDATE THIS MEMBER DATA
int depth, height;
friend class BST<T>;
};
```

Binary search tree class:

```
template <class T>
class BST
{
public:
BST();
~BST();
bool Search(T& val);
bool Search(T& val, BSTNode<T>* node);
void Insert(T& val);
bool DeleteNode(T& val);
void BFT(void);
void PreorderDFT(void);
void PreorderDFT(BSTNode<T>* node);
void PostorderDFT(BSTNode<T>* node);
void InorderDFT(BSTNode<T>* node);
void ComputeNodeDepths(void);
void ComputeNodeHeights(void);
bool IsEmpty(void);
void Visit(BSTNode<T>* node);
void Clear(void);
private:
BSTNode<T> *root;
int depth;
int count;
BSTNode<T> *med; // I've added this member data.
void DelSingle(BSTNode<T>*& ptr);
void DelDoubleByCopying(BSTNode<T>* node);
void ComputeDepth(BSTNode<T>* node, BSTNode<T>* parent);
void ComputeHeight(BSTNode<T>* node);
void Clear(BSTNode<T>* node);
```

};

I tried to write this function: I added two new member data `BSTNode<T>* med`

and `int count`

and this function compute the median only if the number of items is odd:

```
template <class T>
T BST<T>::ComputeMedian()
{
BSTNode<T> *median;
int numOfNodes = CountNodes();
if (numOfNodes % 2 != 0) {
count = 0;
ComputeOddMedian(root, numOfNodes/2);
median = med;
return median->val;
}
else {
count = 0;
ComputeEvenMedian(root, numOfNodes/2);
median = med;
return median->val;
}
return -1;
}
template <class T>
void BST<T>::ComputeOddMedian(BSTNode<T> *node, int x)
{
if (node->left) ComputeOddMedian(node->left, x);
count++;
if (count == x+1)
med = node;
if (node->right) ComputeOddMedian(node->right, x);
}
template <class T>
void BST<T>::ComputeEvenMedian(BSTNode<T> *node, int x)
{
if (node->left) ComputeOddMedian(node->left, x);
count++;
if (count == x-1)
med = node;
if (node->right) ComputeOddMedian(node->right, x);
}
```

It gives right results when the number of items is odd but it causes errors when the number of items is even (I think that is because there might be a NULL pointer). I feel that there is something wrong in my implementation especially with `return`

in the recursion functions and with adding new member data.

*Edit:*
For an odd number of items:

```
int main()
{
BST<int> tree;
int x=12;
tree.Insert(x);
x=6;
tree.Insert(x);
x=22;
tree.Insert(x);
x=3;
tree.Insert(x);
x=10;
tree.Insert(x);
cout << tree.ComputeMedian() << endl;
}
```

For the above code, the output is `10`

which is true.

For an even number of items:

```
int main()
{
BST<int> tree;
int x=12;
tree.Insert(x);
x=6;
tree.Insert(x);
x=22;
tree.Insert(x);
x=3;
tree.Insert(x);
x=10;
tree.Insert(x);
x=17;
tree.Insert(x);
cout << tree.ComputeMedian() << endl;
}
```

For the above code, there is no output and this is a screenshot for the error:

inorderuntil it reaches the proper position then it makes the member med equal to the current node. I think that no matter what ComputeXXXMedian() returns in my code so you can ignore that. – ammarx Jan 26 '14 at 13:54