Stone Game II

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Release: 2024-08-21 06:37:38
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Stone Game II

1140. Stone Game II

Difficulty: Medium

Topics: Array, Math, Dynamic Programming, Prefix Sum, Game Theory

Alice and Bob continue their games with piles of stones. There are a number of piles arranged in a row, and each pile has a positive integer number of stones piles[i]. The objective of the game is to end with the most stones.

Alice and Bob take turns, with Alice starting first. Initially,M = 1.

On each player's turn, that player can take all the stones in the first X remaining piles, where 1 <= X <= 2M. Then, we set M = max(M, X).

The game continues until all the stones have been taken.

Assuming Alice and Bob play optimally, return the maximum number of stones Alice can get.

Example 1:

  • Input: piles = [2,7,9,4,4]
  • Output: 10
  • Explanation: If Alice takes one pile at the beginning, Bob takes two piles, then Alice takes 2 piles again. Alice can get 2 + 4 + 4 = 10 piles in total. If Alice takes two piles at the beginning, then Bob can take all three piles left. In this case, Alice get 2 + 7 = 9 piles in total. So we return 10 since it's larger.

Example 2:

  • Input: piles = [1,2,3,4,5,100]
  • Output: 104

Constraints:

  • 1 <= piles.length <= 100
  • 1 <= piles[i] <= 104

Hint:

  1. Use dynamic programming: the states are (i, m) for the answer of piles[i:] and that given m.

Solution:

We need to use dynamic programming to find the maximum number of stones Alice can get if both players play optimally. Here's a step-by-step approach to develop the solution:

  1. Define the State and Transition:

    • Define a 2D DP array where dp[i][m] represents the maximum stones Alice can collect starting from pile i with a maximum pick limit m.
    • Use a prefix sum array to efficiently calculate the sum of stones in subarrays.
  2. Base Case:

    • If there are no stones left to pick, the score is 0.
  3. Recursive Case:

    • For each pile i and maximum allowed pick m, calculate the maximum stones Alice can collect by considering all possible moves (taking 1 to 2m piles).
  4. Transition Function:

    • For each possible number of piles Alice can pick, compute the total stones Alice can get and use the results of future states to decide the optimal move.

Let's implement this solution in PHP: 1140. Stone Game II

stoneGameII($piles1) . "\n"; // Output: 10
echo $solution->stoneGameII($piles2) . "\n"; // Output: 104
?>




Explanation:

  1. Prefix Sum Calculation: This helps in quickly calculating the sum of stones from any pile i to j.
  2. DP Array Initialization: dp[i][m] holds the maximum stones Alice can get starting from pile i with a maximum pick limit of m.
  3. Dynamic Programming Transition: For each pile and m, compute the maximum stones Alice can collect by iterating over possible pile counts she can take and updating the DP array accordingly.

This approach ensures that the solution is computed efficiently, taking advantage of dynamic programming to avoid redundant calculations.

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