I had this test earlier today, and I tried to be too clever and hit a road block. Unfortunately I got stuck in this mental rut and wasted too much time, failing this portion of the test. I solved it afterward, but maybe y'all can help me get out of the initial rut I was in.
An unordered and non-unique sequence A consisting of N integers (all positive) is given. A subsequence of A is any sequence obtained by removing none, some or all elements from A. The amplitude of a sequence is the difference between the largest and the smallest element in this sequence. The amplitude of the empty subsequence is assumed to be 0.
For example, consider the sequence A consisting of six elements such that:
A = 1 A = 7 A = 6 A = 2 A = 6 A = 4
A subsequence of array A is called quasi-constant if its amplitude does not exceed 1. In the example above, the subsequences [1,2], [6,6], and [6,6,7] are quasi-constant. Subsequence [6, 6, 7] is the longest possible quasi-constant subsequence of A.
Now, find a solution that, given a non-empty zero-indexed array A consisting of N integers, returns the length of the longest quasi-constant subsequence of array A. For example, given sequence A outlined above, the function should return 3, as explained.
Now, I solved this in python 3.6 after the fact using a sort-based method with no classes (my code is below), but I didn't initially want to do that as sorting on large lists can be very slow. It seemed this should have a relatively simple formulation as a breadth-first tree-based class, but I couldn't get it right. Any thoughts on this?
My class-less sort-based solution:
def amp(sub_list): if len(sub_list) <2: return 0 else: return max(sub_list) - min(sub_list) def solution(A): A.sort() longest = 0 idxStart = 0 idxEnd = idxStart + 1 while idxEnd <= len(A): tmp = A[idxStart:idxEnd] if amp(tmp) < 2: idxEnd += 1 if len(tmp) > longest: longest = len(tmp) else: idxStart = idxEnd idxEnd = idxStart + 1 return longest