Let N be the size of the array and M the number of different values in that array.

I'm considering two complexities : pre-processing and querying an interval of size n, each must be spacial and temporal.

**Solution 1 :**
- Spacial : O(1) and O(M)
- Temporal : O(1) and O(n + M)

No pre-processing, we look at all values of the interval and find the most frequent one.

**Solution 2 :**
- Spacial : O(M*N) and O(1)
- Temporal : O(M*N) and O(min(n,M))

For each position of the array, we have an accumulative array that gives us for each value x, how many times x is in the array before that position.

Given an interval we just need for each x to subtract 2 values to find the number of x in that interval. We iterate over each x and find the maximum value. If n < M we iterate over each value of the interval, otherwise we iterate over all possible values for x.

**Solution 3 :**
- Spacial : O(N) and O(1)
- Temporal : O(N) and O(min(n,M)*log(n))

For each value x build a binary heap of all the position in the array where x is present. The key in your heap is the position but you also store the total number of x between this position and the begin of the array.

Given an interval we just need for each x to subtract 2 values to find the number of x in that interval : in O(log(N)) we can ask the x's heap to find the two positions just before the start/end of the interval and substract the numbers. Basically it needs less space than a histogram but the query in now in O(log(N)).