Optimal Binary Search Tree Wrong Output

Question

I am working on a problem that calculates the minimum number of traversals required in a binary search tree by arranging it the best way possible. I did come across a solution online, which I have understood, but I did some calculations of sample inputs by hand, and I did not get the right result.

Following is the code

#include <stdio.h>
#include <limits.h>

// A utility function to get sum of array elements freq[i] to freq[j]
int sum(int freq[], int i, int j);

/* A Dynamic Programming based function that calculates minimum cost of
   a Binary Search Tree. */
int optimalSearchTree(int keys[], int freq[], int n)
{
    /* Create an auxiliary 2D matrix to store results of subproblems */
    int cost[n][n];

    /* cost[i][j] = Optimal cost of binary search tree that can be
       formed from keys[i] to keys[j].
       cost[0][n-1] will store the resultant cost */

    // For a single key, cost is equal to frequency of the key
    for (int i = 0; i < n; i++)
        cost[i][i] = freq[i];

    // Now we need to consider chains of length 2, 3, ... .
    // L is chain length.
    for (int L=2; L<=n; L++)
    {
        // i is row number in cost[][]
        for (int i=0; i<=n-L+1; i++)
        {
            // Get column number j from row number i and chain length L
            int j = i+L-1;
            cost[i][j] = INT_MAX;

            // Try making all keys in interval keys[i..j] as root
            for (int r=i; r<=j; r++)
            {
               // c = cost when keys[r] becomes root of this subtree
               int c = ((r > i)? cost[i][r-1]:0) + 
                       ((r < j)? cost[r+1][j]:0) + 
                       sum(freq, i, j);
               if (c < cost[i][j])
                  cost[i][j] = c;
            }
        }
    }
    return cost[0][n-1];
}

// A utility function to get sum of array elements freq[i] to freq[j]
int sum(int freq[], int i, int j)
{
    int s = 0;
    for (int k = i; k <=j; k++)
       s += freq[k];
    return s;
}

// Driver program to test above functions
int main()
{
    int keys[] = {10, 12, 20};
    int freq[] = {34, 8, 50};
    int n = sizeof(keys)/sizeof(keys[0]);
    printf("Cost of Optimal BST is %d ", optimalSearchTree(keys, freq, n));
    return 0;
}

For instance for the input int keys[] = {1,2,3}; int freq[] = {10,3,1};

I SHOULD GET 18 but i GET 19

FOR THIS INPUT int keys[] = {1,2,3,4}; int freq[] = {5,4,1,200};

I SHOULD GET 225 I GET 226

FOR THIS INPUT int keys[] = {1,2,3,4,5,6}; int freq[] = {33,1,409,2,1,34};

I SHOULD GET 997 but I GET 556

For This Input int keys[] = {1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20}; int freq[] = {5,5,5,5,5,5,5,5,5,5,167,5,5,5,5,5,5,5,5,5};

I Should Get 789 but i GET 532

What is wrong?

Answer 1

You are mistaken about the results to expect. Take your first example, with keys {1, 2, 3} and frequencies {10, 3, 1}; the optimal binary search tree is:

  1 (10)
   \
    2 (3)
     \
      3 (1)

(frequencies given in parentheses). The function returns the expected cost for seaching the tree sum(frequencies) times, as measured by the number of nodes visited, and it is (10 * 1) + (3 * 2) + (1 * 3) = 19. Each search for key 1 traverses only the root node. Each search for key 2 traverses the root node, finding the target key in its child node, for a total of two nodes traversed. Similarly, each search for key 3 traverses three nodes.

It makes sense to measure cost in terms of nodes visited, because a comparison must be made against each visited node's key, but you can also measure cost in terms of edges traversed. The result is identical, however, if you count an edge incoming to the root, representing the host program's pointer to the tree. In that case, every node visit involves traversing that node's incoming edge, erasing any distinction between counting cost in terms of node visits or edge traversals.

With keys {1,2,3,4} and frequencies {5,4,1,200}, the optimal binary search tree is

    4 (200)
   /
  1 (5)
   \
    2 (4)
     \
      3 (1)

with a cost of (200 * 1) + (5 * 2) + (4 * 3) + (1 * 4) = 226.

With keys {1,2,3,4,5,6} and frequencies {33,1,409,2,1,34}:

            3 (409)
          /     \
         /       \
        1 (33)    6 (34)
         \       /
          2 (1)  4 (2)
                  \
                   5(1)

with cost (409 * 1) + ((33 + 34) * 2) + ((1 + 2) * 3) + (1 * 4) = 556.

The program returns the correct result in each case.

I leave the 20-key example as an exercise for you. There are multiple optimal search trees for that case, but all have cost 532, as given by the program.