1937. Maximum Number of Points with Cost
Difficulty: Medium
Topics: Array
, Dynamic Programming
You are given an m x n
integer matrix points
(0-indexed). Starting with 0
points, you want to maximize the number of points you can get from the matrix.
To gain points, you must pick one cell in each row. Picking the cell at coordinates (r, c)
will add points[r][c]
to your score.
However, you will lose points if you pick a cell too far from the cell that you picked in the previous row. For every two adjacent rows r
and r + 1
(where 0 <= r < m - 1
), picking cells at coordinates (r, c1)
and (r + 1, c2)
will subtract abs(c1 - c2)
from your score.
Return the maximum number of points you can achieve.
abs(x)
is defined as:
-
x
forx >= 0
. -
-x
forx < 0
.
Example 1:
- Input: l1 = [2,4,3], l2 = [5,6,4]
- Output: 9
-
Explanation:
- The blue cells denote the optimal cells to pick, which have coordinates (0, 2), (1, 1), and (2, 0).
- You add 3 + 5 + 3 = 11 to your score.
- However, you must subtract abs(2 - 1) + abs(1 - 0) = 2 from your score.
- Your final score is 11 - 2 = 9.
Example 2:
- Input: points = [[1,5],[2,3],[4,2]]
- Output: 11
-
Explanation:
- The blue cells denote the optimal cells to pick, which have coordinates (0, 1), (1, 1), and (2, 0).
- You add 5 + 3 + 4 = 12 to your score.
- However, you must subtract abs(1 - 1) + abs(1 - 0) = 1 from your score.
- Your final score is 12 - 1 = 11.
Constraints:
m == points.length
n == points[r].length
1 <= m, n <= 105
1 <= m * n <= 105
0 <= points[r][c] <= 105
Hint:
- Try using dynamic programming.
- dp[i][j] is the maximum number of points you can have if points[i][j] is the most recent cell you picked.
Solution:
We can break down the solution into several steps:
Step 1: Define the DP Array
We will use a 2D array dp
where dp[i][j]
represents the maximum points we can achieve by selecting the cell at row i
and column j
.
Step 2: Initialize the DP Array
Initialize the first row of dp
to be the same as the first row of points
since there are no previous rows to subtract the cost.
Step 3: Calculate DP Values for Each Row
For each subsequent row, we calculate the maximum possible points for each column considering the costs of switching from the previous row.
To efficiently calculate the transition from row i-1
to row i
, we can use two auxiliary arrays left
and right
:
-
left[j]
will store the maximum value we can achieve for thej
-th column considering only transitions from the left. -
right[j]
will store the maximum value we can achieve for thej
-th column considering only transitions from the right.
Step 4: Update DP for Each Row
For each column j
in row i
:
- Update
dp[i][j]
using the maximum of eitherleft[j]
orright[j]
pluspoints[i][j]
.
Step 5: Return the Maximum Value from the Last Row
The result will be the maximum value in the last row of the dp
array.
Let's implement this solution in PHP: 1937. Maximum Number of Points with Cost
<?php
// Example usage:
$points1 = [[1, 5], [2, 3], [4, 2]];
$points2 = [[2, 4, 3], [5, 6, 4]];
echo maxPoints($points1); // Output: 11
echo maxPoints($points2); // Output: 9
?>
Explanation:
-
left
andright
arrays: These help us compute the maximum points we can gain for each cell by considering the previous row's values, efficiently accounting for the penalty from moving across columns. - Dynamic programming approach: This method ensures that each row is calculated based on the previous row, making the solution scalable for large matrices.
This approach has a time complexity of (O(m \times n)), which is efficient given the constraints.
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