2832. Maximal Range That Each Element Is Maximum in It
Problem Description
You are given an array nums
which contains distinct integers and is 0-indexed. The task is to create another 0-indexed array ans
which corresponds to the array nums
. The value at each index i
in ans
should be the maximum length of a subarray, denoted as nums[l..r]
, where nums[i]
is the largest element in that subarray. The subarray we refer to is a contiguous sequence of elements in the original array, nums
.
To illustrate, if nums
is [1, 3, 2]
, then ans[1]
(corresponding to nums[1]
, which is 3
) would be 3
, since the subarray [1, 3, 2]
with 3
as the maximum element includes all elements in the array.
Intuition
To solve this problem efficiently, we need to determine, for each element nums[i]
, the subarray where it is the maximum element. Specifically, we want to find the indices of the first smaller element to the left and the first smaller element to the right of nums[i]
. These indices essentially bound the subarray where nums[i]
is the maximum element.
The problem can be tackled using a monotonic stack—a stack that maintains its elements in either non-increasing or non-decreasing order. We'll use a non-increasing stack for our purpose.
The intuition behind using a monotonic stack comes from the need to quickly find elements that are smaller than the current element when we traverse the array. By maintaining a non-increasing stack, we ensure that the moment a number smaller than the top of the stack is encountered, it signifies a boundary.
For each position i
in the array, we want to find:
left[i]
: the closest index on the left ofi
wherenums[i]
is less thannums[left[i]]
.right[i]
: The closest index on the right ofi
wherenums[i]
is less thannums[right[i]]
.
To find the left
array values, we iterate through nums
from left to right, and to find the right
array values, we iterate from right to left. During each iteration, we:
- Use the stack to find the next element smaller on the respective side (left or right).
- When pushing an element onto the stack, pop all elements that are not greater than the current element to maintain the non-increasing order.
Finally, for each index i
, we can calculate the maximum range as right[i] - left[i] - 1
, which gives us the length of the largest subarray where nums[i]
is the maximum element.
The resulting array is the ans
array that holds the maximum length of ranges for each nums[i]
.
Learn more about Stack and Monotonic Stack patterns.
Solution Approach
The solution uses a stack as a data structure and a simple algorithm to solve the problem using two passes through the input array. Below is a detailed implementation of the solution approach:
-
Initialize two arrays,
left
andright
, both of the same length asnums
. Theleft
array will store the indices of the closest smaller number to the left of every number innums
, and similarly, theright
array will store the indices of the closest smaller number to the right of every number innums
.- For
left
, initialize all values to-1
to represent that there is no smaller number to the left. - For
right
, initialize all values ton
(the length ofnums
) to represent that there is no smaller number on the right.
- For
-
Initialize an empty list,
stk
, which will serve as the stack. This stack will help to maintain the indices of numbers in a non-increasing order. -
Loop through each element
x
innums
along with its indexi
using the enumerate function. This loop will fill theleft
array.- While the stack is not empty and the last element in the stack (
nums[stk[-1]]
) is less than or equal to the current elementx
:- Pop the element from the stack as it will not be the boundary for any future elements.
- If the stack is not empty after the above step, the current element's left boundary is the last element in the stack, so update
left[i]
withstk[-1]
. - Push the current index
i
onto the stack.
- While the stack is not empty and the last element in the stack (
-
Reset the stack to an empty list for the next phase of the algorithm.
-
Loop through the elements of
nums
in reverse order, starting from the last index, filling in theright
array.- Similar to the forward pass, while the stack isn't empty and the last element in the stack (
nums[stk[-1]]
) is less than or equal tonums[i]
:- Pop the element from the stack.
- If the stack is not empty, update the
right[i]
with the last element in the stack, indicating the closest smaller element on the right. - Push the index
i
onto the stack.
- Similar to the forward pass, while the stack isn't empty and the last element in the stack (
-
After both loops are complete, the
left
andright
arrays contain the boundaries of the subarray where each element is the maximum. -
Calculate the maximum length of ranges for each element
nums[i]
by iterating over theleft
andright
arrays together. For eachi
, subtract the left boundary from the right boundary and subtract1
to find the length of the subrange. This calculation is done list comprehension style to create theans
array:ans = [r - l - 1 for l, r in zip(left, right)]
The ans
array now contains the maximum length of the subarray where the ith element is the maximum for all indices i
.
The main algorithm and data structure patterns used here are:
- Monotonic stack for keeping track of the indices of elements in a non-increasing sequence.
- Two passes through the array to find the ranges: a forward pass for the left boundaries, and a reverse pass for the right boundaries.
- The space complexity of the solution is O(n) due to the additional arrays, and the time complexity is also O(n), because each element is pushed and popped from the stack at most once during each pass.
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Start EvaluatorExample Walkthrough
Let's illustrate the solution approach with a small example. Consider the array nums = [4, 2, 1, 5, 3]
. We want to calculate the array ans
such that each ans[i]
contains the maximum length of a subarray where nums[i]
is the largest element.
-
Initialization:
- Initialize
left
to[-1, -1, -1, -1, -1]
indicating no smaller elements on the left yet. - Initialize
right
to[5, 5, 5, 5, 5]
(sincen = 5
fornums
) indicating no smaller elements on the right yet. - Initialize an empty stack
stk
.
- Initialize
-
Forward Pass (for
left
array):i = 0, x = 4
: Stack is empty, push0
.i = 1, x = 2
:nums[stk[-1]] = 4
>2
, so leave the stack unchanged and push1
.i = 2, x = 1
:nums[stk[-1]] = 2
>1
, so leave the stack unchanged and push2
.i = 3, x = 5
:nums[stk[-1]] = 1
<5
, pop2
.nums[stk[-1]] = 2
<5
, pop1
.nums[stk[-1]] = 4
<5
, pop0
. Stack is now empty, push3
.i = 4, x = 3
: Stack is not empty,left[4] = stk[-1] = 3
. Pop3
since5
>3
. Push4
.
The
left
array is now[-1, -1, -1, -1, 3]
. -
Reverse Pass (for
right
array): Reset the stack tostk = []
.i = 4, x = 3
: Stack is empty, push4
.i = 3, x = 5
: Stack is not empty,right[3] = stk[-1] = 4
. Stack keeps5
.i = 2, x = 1
:nums[stk[-1]] = 3
>1
, so leave the stack unchanged, and push2
.i = 1, x = 2
:nums[stk[-1]] = 1
<2
, pop2
. Nownums[stk[-1]] = 3
>2
, so leave the stack and push1
.i = 0, x = 4
:nums[stk[-1]] = 2
<4
, pop1
.nums[stk[-1]] = 1
<4
, pop2
. Nownums[stk[-1]] = 3
>4
, soright[0] = stk[-1] = 4
, push0
.
The
right
array is now[4, 5, 5, 4, 5]
. -
Calculate the Answer:
-
Calculate the length of the largest subarray where each
nums[i]
is the maximum by subtractingleft
indices fromright
indices and reducing by 1. -
The
ans
array is calculated as follows:ans = [right[i] - left[i] - 1 for i in range(len(nums))]
Thus,
ans = [4 - (-1) - 1, 5 - (-1) - 1, 5 - (-1) - 1, 4 - (-1) - 1, 5 - 3 - 1] = [4, 5, 5, 4, 1]
.
-
The array ans = [4, 5, 5, 4, 1]
is the answer to our problem, where each ans[i]
reflects the maximum subarray length with nums[i]
as the largest element.
Solution Implementation
1from typing import List
2
3class Solution:
4 def maximumLengthOfRanges(self, nums: List[int]) -> List[int]:
5 num_elements = len(nums)
6 # left stores the index of the previous element that is less than nums[i]
7 # If there's no such element, it stores -1
8 left_boundaries = [-1] * num_elements
9 # right stores the index of the next element that is less than nums[i]
10 # If there's no such element, it stores n (length of nums)
11 right_boundaries = [num_elements] * num_elements
12
13 # Stack to keep track of indices where nums[i] is less than the current value
14 stack = []
15
16 # Iterate over each element from the left to find the left boundaries
17 for i, value in enumerate(nums):
18 # Pop from the stack all elements greater than or equal to current value
19 while stack and nums[stack[-1]] <= value:
20 stack.pop()
21 # If stack is not empty, the current value's left boundary is the last element's index
22 if stack:
23 left_boundaries[i] = stack[-1]
24 # Push current index onto the stack
25 stack.append(i)
26
27 # Clear stack for the next iteration
28 stack = []
29
30 # Iterate over each element from the right to find the right boundaries
31 for i in reversed(range(num_elements)):
32 # Pop from the stack all elements greater than or equal to nums[i]
33 while stack and nums[stack[-1]] <= nums[i]:
34 stack.pop()
35 # If stack is not empty, the current value's right boundary is the last element's index
36 if stack:
37 right_boundaries[i] = stack[-1]
38 # Push current index onto the stack
39 stack.append(i)
40
41 # Generate the maximum length of continuous ranges
42 # It's calculated as the difference between right and left boundaries indices minus one
43 return [right - left - 1 for left, right in zip(left_boundaries, right_boundaries)]
44
45# Example usage:
46# solution = Solution()
47# result = solution.maximumLengthOfRanges([10, 5, 2, 6, 5, 3])
48# print(result) # This would print the list of maximum lengths of continuous ranges
49
1import java.util.ArrayDeque;
2import java.util.Arrays;
3import java.util.Deque;
4
5class Solution {
6 public int[] maximumLengthOfRanges(int[] nums) {
7 // The number of elements in the input array
8 int n = nums.length;
9
10 // 'left' array to store the index of the previous smaller element
11 int[] left = new int[n];
12 // 'right' array to store the index of the next smaller element
13 int[] right = new int[n];
14
15 // Initialize 'left' array to -1 and 'right' array to 'n'
16 Arrays.fill(left, -1);
17 Arrays.fill(right, n);
18
19 // Stack to keep track of indices while traversing
20 Deque<Integer> stack = new ArrayDeque<>();
21
22 // Traverse the input array from left to right
23 for (int i = 0; i < n; ++i) {
24 // Pop elements from the stack if they are smaller than or equal to current element
25 while (!stack.isEmpty() && nums[stack.peek()] <= nums[i]) {
26 stack.pop();
27 }
28 // If stack is not empty, set 'left' at the current index to the top element of the stack
29 if (!stack.isEmpty()) {
30 left[i] = stack.peek();
31 }
32 // Push current index to the stack
33 stack.push(i);
34 }
35
36 // Clear the stack for next traversal
37 stack.clear();
38
39 // Traverse the input array from right to left
40 for (int i = n - 1; i >= 0; --i) {
41 // Pop elements from the stack if they are smaller than or equal to current element
42 while (!stack.isEmpty() && nums[stack.peek()] <= nums[i]) {
43 stack.pop();
44 }
45 // If stack is not empty, set 'right' at the current index to the top element of the stack
46 if (!stack.isEmpty()) {
47 right[i] = stack.peek();
48 }
49 // Push current index to the stack
50 stack.push(i);
51 }
52
53 // 'answer' array to store the maximum length ranges
54 int[] answer = new int[n];
55 // Calculate the range length for each element
56 for (int i = 0; i < n; ++i) {
57 // Maximum range length is the difference between right and left indices minus one
58 answer[i] = right[i] - left[i] - 1;
59 }
60
61 // Return the final result array
62 return answer;
63 }
64}
65
1#include <vector>
2#include <stack>
3
4class Solution {
5public:
6 // Function to find the maximum length of ranges for each element in nums,
7 // where the range is defined by the next greater element on both sides.
8 std::vector<int> maximumLengthOfRanges(std::vector<int>& nums) {
9 // Get the size of the input vector.
10 int size = nums.size();
11 // Initialize vectors to store the indices of the next greater element on the left and right.
12 std::vector<int> leftIndices(size, -1);
13 std::vector<int> rightIndices(size, size);
14 // Stack to keep track of indices while finding next greater elements.
15 std::stack<int> indexStack;
16
17 // Iterate from the start to find the next greater element on the left.
18 for (int i = 0; i < size; ++i) {
19 // Pop elements from the stack until a greater element is found.
20 while (!indexStack.empty() && nums[indexStack.top()] <= nums[i]) {
21 indexStack.pop();
22 }
23 // If the stack is not empty, the top element is the next greater element on the left.
24 if (!indexStack.empty()) {
25 leftIndices[i] = indexStack.top();
26 }
27 // Push the current index onto the stack.
28 indexStack.push(i);
29 }
30
31 // Clear the stack to reuse it for the right side search.
32 indexStack = std::stack<int>();
33
34 // Iterate from the end to find the next greater element on the right.
35 for (int i = size - 1; i >= 0; --i) {
36 // Pop elements from the stack until a greater element is found.
37 while (!indexStack.empty() && nums[indexStack.top()] <= nums[i]) {
38 indexStack.pop();
39 }
40 // If the stack is not empty, the top element is the next greater element on the right.
41 if (!indexStack.empty()) {
42 rightIndices[i] = indexStack.top();
43 }
44 // Push the current index onto the stack.
45 indexStack.push(i);
46 }
47
48 // Initialize a vector to hold the maximum lengths of ranges.
49 std::vector<int> maxRangeLengths(size);
50
51 // Calculate the maximum range length for each element in nums.
52 for (int i = 0; i < size; ++i) {
53 // The range length is the difference between the right and left indices, minus one.
54 maxRangeLengths[i] = rightIndices[i] - leftIndices[i] - 1;
55 }
56
57 // Return the vector containing maximum range lengths.
58 return maxRangeLengths;
59 }
60};
61
1function maximumLengthOfRanges(nums: number[]): number[] {
2 const numsLength = nums.length;
3 // 'leftBounds' will hold the index of the previous smaller element for each element.
4 const leftBounds: number[] = Array(numsLength).fill(-1);
5 // 'rightBounds' will hold the index of the next smaller element for each element.
6 const rightBounds: number[] = Array(numsLength).fill(numsLength);
7 const stack: number[] = [];
8
9 // Calculate the previous smaller element's index for each element.
10 for (let i = 0; i < numsLength; ++i) {
11 // Pop elements from the stack until the current element is greater.
12 while (stack.length && nums[stack[stack.length - 1]] <= nums[i]) {
13 stack.pop();
14 }
15 // If there is a previous smaller element, set its index in 'leftBounds'.
16 if (stack.length) {
17 leftBounds[i] = stack[stack.length - 1];
18 }
19 // Push the current index onto the stack.
20 stack.push(i);
21 }
22
23 // Clear the stack to reuse it for right bounds calculation.
24 stack.length = 0;
25
26 // Calculate the next smaller element's index for each element (reverse iteration).
27 for (let i = numsLength - 1; i >= 0; --i) {
28 // Pop elements from the stack until the current element is greater.
29 while (stack.length && nums[stack[stack.length - 1]] <= nums[i]) {
30 stack.pop();
31 }
32 // If there is a next smaller element, set its index in 'rightBounds'.
33 if (stack.length) {
34 rightBounds[i] = stack[stack.length - 1];
35 }
36 // Push the current index onto the stack.
37 stack.push(i);
38 }
39
40 // Compute the maximum length of ranges for each element.
41 const maxLengths = leftBounds.map((leftBound, i) => rightBounds[i] - leftBound - 1);
42 return maxLengths;
43}
44
Time and Space Complexity
The given Python code aims to find the maximum length of ranges for each element in a list, where the range is limited by elements that are strictly greater than the current element on both sides.
The time complexity of the code can be analyzed based on the two for-loops used to find the left
and right
boundaries for each element:
-
The first for-loop goes through each element in the list
nums
from left to right. For each element at indexi
, it pops elements off the stackstk
until it finds an element that is greater thannums[i]
. This operation is essentially an amortized O(1) operation because each element is pushed onto the stack and popped at most once, leading to a total of O(n) operations wheren
is the number of elements innums
. -
The second for-loop is similar to the first one but iterates from right to left. It has the same amortized O(1) complexity per element for the same reason as the first loop.
Taking both loops into account, the overall time complexity of the code is O(n)
.
For space complexity:
-
The additional space used by the algorithm includes the
stk
stack, theleft
, andright
arrays. The length of the stack will at most equal the number of elements innums
(in the case when the elements are sorted in non-decreasing order), which contributesO(n)
space complexity. -
The
left
andright
arrays each have the same length asnums
, contributing twiceO(n)
space, but this is still considered O(n) because constant factors are ignored in Big O notation.
Given this, the overall space complexity is also O(n)
as the stack and the arrays left
and right
are linear in size to the input size n
.
So, the code has a time complexity of O(n)
and a space complexity of O(n)
.
Learn more about how to find time and space complexity quickly using problem constraints.
Which of the following shows the order of node visit in a Breadth-first Search?
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