You are given K eggs, and you have access to a building with N floors from 1 to N.

Each egg is identical in function, and if an egg breaks, you cannot drop it again.

You know that there exists a floor F with 0 <= F <= N such that any egg dropped at a floor higher than F will break, and any egg dropped at or below floor F will not break.

Each move, you may take an egg (if you have an unbroken one) and drop it from any floor X (with 1 <= X <= N).

Your goal is to know with certainty what the value of F is.

What is the minimum number of moves that you need to know with certainty what F is, regardless of the initial value of F?

Example 1:

Input: K = 1, N = 2

Output: 2

Explanation:

Drop the egg from floor 1.  If it breaks, we know with certainty that F = 0.

Otherwise, drop the egg from floor 2.  If it breaks, we know with certainty that F = 1.

If it didn't break, then we know with certainty F = 2.

Hence, we needed 2 moves in the worst case to know what F is with certainty.

Example 2:

Input: K = 2, N = 6

Output: 3

Example 3:

Input: K = 3, N = 14

Output: 4

Note:

1. 1 <= K <= 100
2. 1 <= N <= 10000

Approach #1: DP. [C++][TLE][O(K*N^2)]

class Solution {

public:

    int superEggDrop(int K, int N) {

        int c = 0;

        vector<vector<int>> dp(K+1, vector<int>(N+1, 0));

        for (int i = 1; i <= N; ++i) dp[1][i] = i;

        for (int i = 2; i <= K; ++i) {

            for (int j = 1; j <= N; ++j) {

                dp[i][j] = INT_MAX;

                for (int k = 1; k <= j; ++k) {

                    c = 1 + max(dp[i-1][k-1], dp[i][j-k]);

                    if (c < dp[i][j])

                        dp[i][j] = c;

                }

            }

        }

        return dp[K][N];

    }

};

Approach #2: DP. [Java]

class Solution {

    public int superEggDrop(int K, int N) {

        int[][] dp = new int[N+1][K+1];

        int m = 0;

        while (dp[m][K] < N) {

            ++m;

            for (int k = 1; k <= K; ++k)

                dp[m][k] = dp[m-1][k-1] + dp[m-1][k] + 1;

        }

        return m;

    }

}

Analysis:

Firstly, if we have K eggs and s steps to detect a buliding with Q(k, s) floors.

Secondly, we use 1 egg and 1 step to detect one floor,

if egg break, we can use (k-1) eggs and (s-1) to detect with Q(k-1, s-1),

if egg isn't broken, we can use k eggs and (s-1) step to detech with Q(k, s-1),

So, Q(k,s) = 1 + Q(k, s-1) + Q(k-1, s-1);

dp[i] is max floors we can use i eggs and s step to detect.

Reference:

https://leetcode.com/problems/super-egg-drop/discuss/159508/easy-to-understand