Description#
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 for x >= 0.-x for x < 0.
Example 1:
Input: points = [[1,2,3],[1,5,1],[3,1,1]]
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.lengthn == points[r].length1 <= m, n <= 1051 <= m * n <= 1050 <= points[r][c] <= 105
Solutions#
Solution 1#
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| class Solution:
def maxPoints(self, points: List[List[int]]) -> int:
n = len(points[0])
f = points[0][:]
for p in points[1:]:
g = [0] * n
lmx = -inf
for j in range(n):
lmx = max(lmx, f[j] + j)
g[j] = max(g[j], p[j] + lmx - j)
rmx = -inf
for j in range(n - 1, -1, -1):
rmx = max(rmx, f[j] - j)
g[j] = max(g[j], p[j] + rmx + j)
f = g
return max(f)
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| class Solution {
public long maxPoints(int[][] points) {
int n = points[0].length;
long[] f = new long[n];
final long inf = 1L << 60;
for (int[] p : points) {
long[] g = new long[n];
long lmx = -inf, rmx = -inf;
for (int j = 0; j < n; ++j) {
lmx = Math.max(lmx, f[j] + j);
g[j] = Math.max(g[j], p[j] + lmx - j);
}
for (int j = n - 1; j >= 0; --j) {
rmx = Math.max(rmx, f[j] - j);
g[j] = Math.max(g[j], p[j] + rmx + j);
}
f = g;
}
long ans = 0;
for (long x : f) {
ans = Math.max(ans, x);
}
return ans;
}
}
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| class Solution {
public:
long long maxPoints(vector<vector<int>>& points) {
using ll = long long;
int n = points[0].size();
vector<ll> f(n);
const ll inf = 1e18;
for (auto& p : points) {
vector<ll> g(n);
ll lmx = -inf, rmx = -inf;
for (int j = 0; j < n; ++j) {
lmx = max(lmx, f[j] + j);
g[j] = max(g[j], p[j] + lmx - j);
}
for (int j = n - 1; ~j; --j) {
rmx = max(rmx, f[j] - j);
g[j] = max(g[j], p[j] + rmx + j);
}
f = move(g);
}
return *max_element(f.begin(), f.end());
}
};
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| func maxPoints(points [][]int) int64 {
n := len(points[0])
const inf int64 = 1e18
f := make([]int64, n)
for _, p := range points {
g := make([]int64, n)
lmx, rmx := -inf, -inf
for j := range p {
lmx = max(lmx, f[j]+int64(j))
g[j] = max(g[j], int64(p[j])+lmx-int64(j))
}
for j := n - 1; j >= 0; j-- {
rmx = max(rmx, f[j]-int64(j))
g[j] = max(g[j], int64(p[j])+rmx+int64(j))
}
f = g
}
return slices.Max(f)
}
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| function maxPoints(points: number[][]): number {
const n = points[0].length;
const f: number[] = new Array(n).fill(0);
for (const p of points) {
const g: number[] = new Array(n).fill(0);
let lmx = -Infinity;
let rmx = -Infinity;
for (let j = 0; j < n; ++j) {
lmx = Math.max(lmx, f[j] + j);
g[j] = Math.max(g[j], p[j] + lmx - j);
}
for (let j = n - 1; ~j; --j) {
rmx = Math.max(rmx, f[j] - j);
g[j] = Math.max(g[j], p[j] + rmx + j);
}
f.splice(0, n, ...g);
}
return Math.max(...f);
}
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