I am a C++ newbie, not quite understand the destruction workflow of this program, so I write destructor for both classes. But got error... Do I bother defining the destructor of Node?

```
#include<iostream>
using namespace std;
// in this case, the BST doesn't have duplicates
class Node
{
public:
Node* parent;
Node* left;
Node* right;
Node() : key(-1), parent(NULL), left(NULL), right(NULL) {}
virtual ~Node() {cout << "destructor of Node" << endl; delete parent; delete left; delete right;}
void setKey(int k)
{
key = k;
}
int getKey() {return key;}
private:
int key;
};
class BST
{
public:
Node* root;
BST() {root = NULL;}
virtual ~BST() {freeNode(root);}
void addNode(int key)
{
if (!root)
{
root = new Node();
root->setKey(key);
}
else
addNode(key, root);
}
Node* findNode(int key)
{
Node* p = root;
while (p)
{
if (p->getKey() == key)
return p;
else if (p->getKey()<=key)
{
p = p->right;
}
else
p = p->left;
}
return p;
}
void walk(Node* node)
{
if (node)
{
walk(node->left);
cout << node->getKey() << " " << flush;
walk(node->right);
}
}
void deleteNode(int key)
{
Node* p = findNode(key);
if (p)
{
//case 1: p has no children
if (!p->right && !p->left)
p->parent->right == p ? p->parent->right = NULL : p->parent->left = NULL;
//case 2: p has one child
else if (!p->left && p->right)
{
p->parent->right = p->right;
freeNode(p);
}
else if (!p->right && p->left)
{
p->parent->left = p->left;
freeNode(p);
}
//case 3: p has two children
else
{
Node *suc = successor(key);
exchange(suc,p);
deleteNode(suc->getKey());
}
}
}
Node* min(Node* node)
{
//empty tree
if (!node)
return NULL;
else if (!node->left)
return node;
else
return min(node->left);
}
Node* max(Node* node)
{
//empty tree
if(!node)
return NULL;
else if (!node->right)
return node;
else
return max(node->right);
}
Node* successor(int key)
{
Node *temp = NULL;
Node *p = findNode(key);
//case 1: has a right child
if (p->right)
return min(p->right);
//case 2: does not have a right child
else
{
temp = p->parent;
while(temp->left != p)
{
p = temp;
temp = temp->parent;
}
return temp;
}
}
Node* predecessor(int key)
{
Node *temp = NULL;
Node *p = findNode(key);
//case1: has a left child
if (p->left)
return max(p->left);
//case2: does not have a left child
else
{
temp = p->parent;
while(temp->right != p)
{
p = temp;
temp = temp->parent;
}
return temp;
}
}
private:
void addNode(int key, Node* node)
{
if (node->getKey() <= key)
{
if (node->right)
addNode(key, node->right);
else
{
Node* leaf = new Node();
leaf->setKey(key);
leaf->parent = node;
node->right = leaf;
}
}
else
{
if (node->left)
addNode(key, node->left);
else
{
Node* leaf = new Node();
leaf->setKey(key);
leaf->parent = node;
node->left = leaf;
}
}
}
void freeNode(Node* leaf)
{
delete leaf;
}
void exchange(Node *a, Node *b)
{
int temp = a->getKey();
a->setKey(b->getKey());
b->setKey(temp);
}
};
int main(int argc, char** args)
{
int *p = NULL;
delete p;
BST tree;
tree.addNode(8);
tree.addNode(4);
tree.addNode(12);
tree.addNode(2);
tree.addNode(6);
tree.addNode(10);
tree.addNode(14);
tree.addNode(1);
tree.addNode(3);
tree.addNode(5);
tree.addNode(7);
tree.addNode(9);
tree.addNode(11);
tree.addNode(13);
tree.addNode(15);
tree.walk(tree.root);
return 0;
}
```