Here is a successful code implementation for the same along with the driver program:

```
#include <iostream>
using namespace std;
class BinaryTree {
public:
BinaryTree *right;
BinaryTree *left;
int value;
BinaryTree(int value) {
this->value = value;
}
};
int max_value(int a, int b) {
if (a > b) {
return a;
} else {
return b;
}
}
int min_value(int a, int b) {
if (a < b) {
return a;
} else {
return b;
}
}
BinaryTree* findLargestBST(BinaryTree *n, int* maxSize, int *max, int *min, bool *is_bst) {
if (n == NULL) {
*maxSize = 0;
*is_bst = true;
return n;
}
int *lc_max_size = new int;
int *rc_max_size = new int;
int *lc_max = new int;
int *lc_min = new int;
int *rc_max = new int;
int *rc_min = new int;
*lc_max = std::numeric_limits<int>::min();
*rc_max = *lc_max;
*lc_min = std::numeric_limits<int>::max();
*rc_min = *lc_min;
BinaryTree* returnPointer;
bool is_curr_bst = true;
BinaryTree* lc = findLargestBST(n->left, lc_max_size, lc_max, lc_min, is_bst);
if (!*is_bst) {
is_curr_bst = false;
}
BinaryTree* rc = findLargestBST(n->right, rc_max_size, rc_max, rc_min, is_bst);
if (!*is_bst) {
is_curr_bst = false;
}
if (is_curr_bst && *lc_max <= n->value && n->value <= *rc_min) {
*is_bst = true;
*maxSize = 1 + *lc_max_size + *rc_max_size;
returnPointer = n;
*max = max_value (n->value, *rc_max);
*min = min_value (n->value, *lc_min);
} else {
*is_bst = false;
*maxSize = max_value(*lc_max_size, *rc_max_size);
if (*maxSize == *lc_max_size) {
returnPointer = lc;
} else {
returnPointer = rc;
}
*max = *min = n->value;
}
delete lc_max_size;
delete rc_max_size;
delete lc_max;
delete lc_min;
delete rc_max;
delete rc_min;
return returnPointer;
}
int main() {
/* Let us construct the following Tree
50
/ \
10 60
/ \ / \
5 20 55 70
/ / \
45 65 80
*/
BinaryTree *root = new BinaryTree(50);
root->left = new BinaryTree(10);
root->right = new BinaryTree(60);
root->left->left = new BinaryTree(5);
root->left->right = new BinaryTree(20);
root->right->left = new BinaryTree(55);
root->right->left->left = new BinaryTree(45);
root->right->right = new BinaryTree(70);
root->right->right->left = new BinaryTree(65);
root->right->right->right = new BinaryTree(80);
/* The complete tree is not BST as 45 is in right subtree of 50.
The following subtree is the largest BST
60
/ \
55 70
/ / \
5 65 80
*/
int *maxSize = new int;
int *min_value = new int;
int *max_value = new int;
*min_value = std::numeric_limits<int>::max();
*max_value = std::numeric_limits<int>::min();
bool *is_bst = new bool;
BinaryTree *largestBSTNode = findLargestBST(root, maxSize, max_value, min_value, is_bst);
printf(" Size of the largest BST is %d", *maxSize);
printf("Max size node is %d", largestBSTNode->value);
delete maxSize;
delete min_value;
delete max_value;
delete is_bst;
getchar();
return 0;
}
```

The approach used is fairly straightforward and can be understood as follows:

It is a *bottom to top approach* instead of a top to bottom one which we use when determining whether the tree is a BST or not. It uses the same max-min approach used while determining the tree as a BST or not.

Following are the steps which are executed at each of the nodes in a recursive fashion:
*Note: Please remember that this is a bottom up approach and the information is going to flow from the bottom to the top.*

1) Determine whether I am existent or not. If I am not (I am null) I should not influence the algorithm in any way and should return without doing any modifications.

2) At every node, maximum size of the BST till this point is stored. This is determined using the total size of the left subtree + the total size of the right subtree + 1(for the node itself) if the tree at this particular node satisfies the BST property. Otherwise, it is figured out from the max values that have been returned from the left subtree and the right subtree.

3) In the case if the BST property is satisfied at the given node then the current node is returned as the maximum size BST till this point otherwise it is determined from the left and the right subtrees.