2780. Minimum Index of a Valid Split
Problem Description
In this problem, we are provided with an integer array arr
where a dominant element is defined as an element x
that appears more than half of the time in arr
(freq(x) * 2 > m
, where m
is the length of arr
). The array nums
we're working with is guaranteed to contain one such dominant element.
The task is to find a valid split for the array nums
into two subarrays where both subarrays contain the same dominant element. A split at index i
is valid if 0 <= i < n - 1
(where n
is the length of nums
), and both resulting subarrays (nums[0, ..., i]
and nums[i + 1, ..., n - 1]
) have the same dominant element. The goal is to find the minimum index i
at which such a valid split can occur. If there is no possible valid split, we should return -1
.
To give a simple example, if nums
is [2,2,1,2,2]
, splitting after the second 2
results in [2,2]
and [1,2,2]
, both of which have 2
as the dominant element. So the index before which we split would be 2-1
(because it's 0-indexed), hence the minimum valid split index would be 1
.
Intuition
The provided solution approach relies on the definition of a dominant element and some properties of an array with exactly one dominant element:
- Because there is only one dominant element, once we find it, we know it will be the dominant element in any valid split.
- Since the dominant element appears more than half the time, the first candidate for a possible split can only occur after we first encounter this condition in the running count of the dominant element.
Given these principles, the steps to arrive at the solution involve:
- Finding the dominant element using a counter to determine the most common element in the array.
- Iterating through the array, keeping track of the count of occurrences of the dominant element (
cur
). - As we iterate, we check two conditions at each index
i
:- If
cur * 2 > i
, it means the dominant element is currently more than half of the elements from0
toi-1
. - Simultaneously, we must check if the dominant element will remain dominant in the second subarray. This is done by checking if
(cnt - cur) * 2 > len(nums) - i
, wherecnt
is the total occurrences of the dominant element, andlen(nums) - i
is the length of the second subarray.
- If
As soon as both conditions are satisfied, it indicates we've found a valid split. The solution outputs the index i - 1
, accounting for the 0-indexed array.
By iterating over the array just once and checking the conditions, the solution effectively finds the minimum index for a valid split, thereby solving the problem in linear time with respect to the length of the array.
Learn more about Sorting patterns.
Solution Approach
The solution begins by using a Counter
from the collections
module to find the most common element in the array nums
, which is the dominant element by the problem's definition. The Counter
is a dictionary subclass designed for counting hashable objects, and the most_common(1)
method retrieves the most common element along with its count.
x, cnt = Counter(nums).most_common(1)[0]
In this line of the code, x
stands for the dominant element, while cnt
is the number of times x
appears in nums
.
Next, the code uses a single-pass for loop to iterate over all the elements of the array while keeping track of two things:
- The count of the dominant element seen so far (
cur
). - The index at which this count is processed (
i
), which is used for checking whether a split is valid.
for i, v in enumerate(nums, 1):
Here, enumerate
is used with a start index of 1
to keep the index i
synchronized with the length of the subarray being considered, since we're interested in the possibility of a split before the i-th
element.
The iteration follows this logic:
- Increment
cur
each time the dominant element is encountered.
if v == x: cur += 1
- Check if we can make a valid split at index
i-1
. This check has two parts:
-
To ensure that the dominant element is indeed dominant in the first subarray, we check if
cur * 2 > i
. This guarantees that there are more instances ofx
than all other elements combined until the current index. -
To ensure that the dominating element is also dominant in the second subarray after the split, we check if
(cnt - cur) * 2 > len(nums) - i
. This ensures that even after removingcur
instances ofx
, we have enough left forx
to remain dominant.
if cur * 2 > i and (cnt - cur) * 2 > len(nums) - i:
return i - 1
If both conditions are satisfied, the current i
represents a 1-indexed position at which an array can be split. Since the requested output should be 0-indexed, i - 1
is returned.
If the for loop completes without returning, it means no valid split exists that satisfies both conditions, and in this case, the function returns -1
.
return -1
By employing a count tracking approach, the conditionals are checked in O(1)
time per element, leading to an overall time complexity of O(n)
, where n
is the number of elements in the array. The space complexity is also O(n)
since we use a Counter to store the frequency of each element in the array.
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Start EvaluatorExample Walkthrough
Let's consider a small example with the following array of numbers:
nums = [3, 3, 4, 2, 3]
Using this array, we'll walk through the solution approach described above.
- First, we need to determine the dominant element in the array. We do this by utilizing the
Counter
class from thecollections
module:
from collections import Counter x, cnt = Counter(nums).most_common(1)[0]
In our example, x
will be 3
since it's the most common element, and cnt
will be 3
because 3
appears three times in the array.
- Then, we proceed to iterate over the array and count the occurrences of the dominant element while simultaneously checking if a valid split is possible:
cur = 0
for i, v in enumerate(nums, 1):
if v == x:
cur += 1
if cur * 2 > i and (cnt - cur) * 2 > len(nums) - i:
return i - 1
-
We examine each element in the loop:
- At
i = 1
(3
):cur
becomes1
. We cannot split yet becausecur * 2
is not greater thancnt
. - At
i = 2
(3
):cur
becomes2
. We cannot split yet because, althoughcur * 2
is now4
and greater than2
, the second condition(cnt - cur) * 2 > len(nums) - i
is not met (as1 * 2
is not greater than3
). - At
i = 3
(4
):cur
remains2
. We still can't split because the first condition is no longer fulfilled. - At
i = 4
(2
):cur
remains2
. Once again, we can't split due to the first condition not being met. - At
i = 5
(3
):cur
becomes3
. This is the first time a split is possible ascur * 2
is6
and greater than5
, and(cnt - cur) * 2
is0
, which is less thanlen(nums) - i
which is0
.
- At
# Since we have reached the end of the array, # and there is no point where both conditions were true, # the result of the function would be: return -1
In this example, there is no valid split because at no point do both conditions satisfy during the iteration. Thus, according to our solution, the function would return -1
, meaning no valid minimum index split exists.
Solution Implementation
1from typing import List
2from collections import Counter
3
4class Solution:
5 def minimumIndex(self, nums: List[int]) -> int:
6 # Get the most common element and its count
7 most_common_element, count_most_common = Counter(nums).most_common(1)[0]
8
9 # 'current_count' will keep track of the occurrences of the most common element
10 current_count = 0
11
12 # Enumerate over the array to find the split index
13 for index, value in enumerate(nums):
14 # Increment the count if current value is the most common element
15 if value == most_common_element:
16 current_count += 1
17
18 # Calculate the current index (1-indexed in the given code, so index + 1)
19 current_index = index + 1
20
21 # Check if our current count is greater than the half of the current index
22 # and if the remaining count of the most common element is greater
23 # than the half of the rest of the list
24 if (current_count * 2 > current_index) and \
25 ((count_most_common - current_count) * 2 > (len(nums) - current_index)):
26 # Return the index (convert it back to 0-indexed by subtracting 1)
27 return index
28
29 # If no such index is found, return -1
30 return -1
31
32# Example usage:
33# solution = Solution()
34# result = solution.minimumIndex([1, 3, 2, 3, 2, 3, 3])
35# print(result) # It should print the index if it satisfies the condition, otherwise -1
36
1class Solution {
2
3 // Method to find the minimum index where the most frequent number occurs
4 // more frequently than all other numbers both to the left and to the right of the index.
5 public int minimumIndex(List<Integer> nums) {
6 int mostFrequentNum = 0; // variable to store the most frequent number
7 int maxFrequency = 0; // variable to store the maximum frequency count
8 Map<Integer, Integer> frequencyMap = new HashMap<>(); // map to store the frequency of each number
9
10 // Count frequencies of each number in nums using a hashmap and record the most frequent number.
11 for (int value : nums) {
12 int currentFrequency = frequencyMap.merge(value, 1, Integer::sum);
13 if (maxFrequency < currentFrequency) {
14 maxFrequency = currentFrequency;
15 mostFrequentNum = value;
16 }
17 }
18
19 // Iterate over the list to find the minimum index where the most frequent number
20 // is more common than other elements to its left and right.
21 int currentFreqCount = 0; // to keep the running count of the most frequent number
22 for (int i = 1; i <= nums.size(); i++) {
23 if (nums.get(i - 1).equals(mostFrequentNum)) {
24 currentFreqCount++;
25 // Check if the most frequent number is more frequent than the remaining numbers
26 // on both sides of the current index.
27 if (currentFreqCount * 2 > i && (maxFrequency - currentFreqCount) * 2 > nums.size() - i) {
28 return i - 1; // Return the index if condition is met
29 }
30 }
31 }
32
33 return -1; // Return -1 if no such index is found
34 }
35}
36
1#include <vector>
2#include <unordered_map>
3using namespace std;
4
5class Solution {
6public:
7 int minimumIndex(vector<int>& nums) {
8 int x = 0; // Variable to keep track of the most frequent value encountered.
9 int countMaxFreq = 0; // Counter to store the maximum frequency of an element.
10 unordered_map<int, int> freqMap; // Map to keep track of the frequency of each element in 'nums'.
11
12 // Count the frequency of each element and find the element with the highest frequency.
13 for (int value : nums) {
14 ++freqMap[value];
15 // Update the most frequent element and its count accordingly
16 if (freqMap[value] > countMaxFreq) {
17 countMaxFreq = freqMap[value];
18 x = value;
19 }
20 }
21
22 int currentCount = 0; // Counter to track the number of occurrences of 'x' encountered so far.
23
24 // Loop through the array to find the index where 'x' becomes the majority element
25 // in both the prefix (left of index) and the suffix (right of index).
26 // The condition to check for majority is that the number of occurrences of 'x' should
27 // be more than half of the current index when considering prefix and more than half of
28 // the remaining elements when considering the suffix.
29 for (int i = 1; i <= nums.size(); ++i) {
30 if (nums[i - 1] == x) {
31 ++currentCount;
32 // Check if 'x' is the majority element in both the prefix and suffix.
33 if (currentCount * 2 > i && (countMaxFreq - currentCount) * 2 > nums.size() - i) {
34 return i - 1; // Found the index, returning the 0-based index.
35 }
36 }
37 }
38
39 // If no such index is found, return -1.
40 return -1;
41 }
42};
43
1function minimumIndex(nums: number[]): number {
2 // Initialize the majority element 'majorityElement' and its count 'majorityCount'.
3 let [majorityElement, majorityCount] = [0, 0];
4 // Create a Map to store the frequency of each element in 'nums'.
5 const frequencyMap: Map<number, number> = new Map();
6
7 // Calculate the frequency of each element and find the majority element.
8 for (const value of nums) {
9 const updatedCount = (frequencyMap.get(value) ?? 0) + 1;
10 frequencyMap.set(value, updatedCount);
11 // Update the majority element if the current value becomes the new majority.
12 if (updatedCount > majorityCount) {
13 [majorityElement, majorityCount] = [value, updatedCount];
14 }
15 }
16
17 // Initialize the count of majority element encountered so far.
18 let currentCount = 0;
19 // Iterate over the array to find the minimum index that satisfies the conditions.
20 for (let i = 1; i <= nums.length; ++i) {
21 // If the current element is the majority element, increment count.
22 if (nums[i - 1] === majorityElement) {
23 currentCount++;
24 // Check if the element is in majority in both the parts of the array.
25 if (
26 (currentCount * 2 > i) && // Majority in first part
27 ((majorityCount - currentCount) * 2 > nums.length - i) // Majority in second part
28 ) {
29 // Return the index if both parts have the same majority element.
30 return i - 1;
31 }
32 }
33 }
34
35 // Return `-1` if no such index is found.
36 return -1;
37}
38
Time and Space Complexity
Time Complexity
The given Python function minimumIndex
first determines how many times the most common number x
occurs in the array nums
by using the Counter
class from the collections
module and retrieves the count cnt
. This operation is O(n)
where n
is the length of the list nums
, as it involves iterating through the entire list to compute the frequency of each element.
Following that, the function proceeds to iterate through the list nums
while maintaining a cumulative count cur
of how often it has encountered x
so far. During iteration, it performs a constant time check in each iteration to determine if cur
and cnt - cur
are both more than half of the numbers seen so far and the numbers remaining, respectively.
The loop also iterates n
times in the worst case (if it does not return early), so the total time complexity of the entire function thus remains O(n)
, where n
is the length of the input list.
The exact time complexity is therefore O(n)
.
Space Complexity
In terms of space, the function uses additional memory for the Counter
object to store the frequency of each element in nums
. The space complexity for this part is O(m)
, where m
denotes the number of unique elements in nums
. In the worst case where all elements are unique, m
would be equivalent to n
, resulting in O(n)
space complexity.
Additionally, the space used for the index counter i
, the most common element and its count (x, cnt)
and the running count cur
is O(1)
, as they do not depend on the size of the input list but are merely constant size variables.
Thus, the overall space complexity of the function is O(m)
, which is O(n)
in the worst case when all elements in nums
are unique.
The exact space complexity is O(m)
with a note that it simplifies to O(n)
in the worst-case scenario.
Learn more about how to find time and space complexity quickly using problem constraints.
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