1802. Maximum Value at a Given Index in a Bounded Array
Description
You are given three positive integers: n
, index
, and maxSum
. You want to construct an array nums
(0-indexed) that satisfies the following conditions:
nums.length == n
nums[i]
is a positive integer where0 <= i < n
.abs(nums[i] - nums[i+1]) <= 1
where0 <= i < n-1
.- The sum of all the elements of
nums
does not exceedmaxSum
. nums[index]
is maximized.
Return nums[index]
of the constructed array.
Note that abs(x)
equals x
if x >= 0
, and -x
otherwise.
Example 1:
Input: n = 4, index = 2, maxSum = 6 Output: 2 Explanation: nums = [1,2,2,1] is one array that satisfies all the conditions. There are no arrays that satisfy all the conditions and have nums[2] == 3, so 2 is the maximum nums[2].
Example 2:
Input: n = 6, index = 1, maxSum = 10 Output: 3
Constraints:
1 <= n <= maxSum <= 109
0 <= index < n
Solutions
Solution 1: Binary Search
According to the problem description, if we determine the value of $nums[index]$ as $x$, we can find a minimum array sum. That is, the elements on the left side of $index$ in the array decrease from $x-1$ to $1$, and if there are remaining elements, the remaining elements are all $1$; similarly, the elements at $index$ and on the right side of the array decrease from $x$ to $1$, and if there are remaining elements, the remaining elements are all $1$.
In this way, we can calculate the sum of the array. If the sum is less than or equal to $maxSum$, then the current $x$ is valid. As $x$ increases, the sum of the array will also increase, so we can use the binary search method to find the maximum $x$ that meets the conditions.
To facilitate the calculation of the sum of the elements on the left and right sides of the array, we define a function $sum(x, cnt)$, which represents the sum of an array with $cnt$ elements and a maximum value of $x$. The function $sum(x, cnt)$ can be divided into two cases:
- If $x \geq cnt$, then the sum of the array is $\frac{(x + x - cnt + 1) \times cnt}{2}$
- If $x \lt cnt$, then the sum of the array is $\frac{(x + 1) \times x}{2} + cnt - x$
Next, define the left boundary of the binary search as $left = 1$, the right boundary as $right = maxSum$, and then binary search for the value $mid$ of $nums[index]$. If $sum(mid - 1, index) + sum(mid, n - index) \leq maxSum$, then the current $mid$ is valid, we can update $left$ to $mid$, otherwise we update $right$ to $mid - 1$.
Finally, return $left$ as the answer.
The time complexity is $O(\log M)$, where $M=maxSum$. The space complexity is $O(1)$.
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