5

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.

Problem definition:

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[0] = 1
A[1] = 7
A[2] = 6
A[3] = 2
A[4] = 6
A[5] = 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
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  • You say that "sorting on large lists can be very slow" but sorting has time complexity O(n log n) and is highly optimized. Most tree algorithms have the same time complexity and are not optimized. Why do you think a tree algorithm would be better than a sort-based one? (A good sort-based solution is O(n) after the sort.) Apr 1 '18 at 0:37
  • I guess you make a good point. Seems I definitely was overthinking the problem.
    – NichD
    Apr 2 '18 at 1:07
4

I don't know how BFS is supposed to help here.

Why not simply run once through the sequence and count how many elements every possible quasi-constant subsequence would have?

from collections import defaultdict

def longestQuasiConstantSubseqLength(seq):
  d = defaultdict(int)
  for s in seq:
    d[s] += 1
    d[s+1] += 1
  return max(d.values() or [0])

s = [1,7,6,2,6,4]

print(longestQuasiConstantSubseqLength(s))

prints:

3

as expected.

Explanation: Every non-constant quasi-constant subsequence is uniquely identified by the greatest number that it contains (there can be only two, take the greater one). Now, if you have a number s, it can either contribute to the quasi-constant subsequence that has s or s + 1 as the greatest number. So, just add +1 to the subsequences identified by s and s + 1. Then output the maximum of all counts.

You can't get it faster than O(n), because you have to look at every entry of the input sequence at least once.

6
  • nice solution. Suggestions: d = defaultdict(lambda: 0) can be replaced by d = defaultdict(int); need to handle empty seq: return max(d.values() or [0])
    – Marat
    Apr 1 '18 at 0:54
  • @Marat, Thanks for feedback! It took a moment to understand that the nullary int() function produces 0 as default int. Will update in a second. Apr 1 '18 at 1:01
  • @Marat, Updated, hopefully increased pythonicity. :] Seriously thank you! Apr 1 '18 at 1:03
  • This is equivalent to a solution I was going to write using collections.Counter. My approach would have been to count the items only under their actual value, but add together the values of adjacent keys in the max call (e.g. max(counts[x]+counts[x+1] for x in counts)). Both are O(n), and I doubt there'd be much performance difference between them.
    – Blckknght
    Apr 1 '18 at 1:11
  • @Blckknght Thanks Blckknght, indeed, a Counter would be sufficient. One could actually combine the two solutions simply by replacing defaultdict[k] += 1 by increment of the corresponding counter. My usage of python collections might be not 100% adequate yet, learnt about the defaultdict just today, tried to use it somewhere :] Typical hammer-nail problem, actually :D Apr 1 '18 at 1:13
4

As Andrey Tyukin pointed out, you can solve this problem in O(n) time, which is better than the O(n log n) time you'd likely get from either sorting or any kind of tree based solution. The trick is to use dictionaries to count the number of occurrences of each number in the input, and use the count to figure out the longest subsequence.

I had a similar idea to him, but I had though of a slightly different implementation. After a little testing, it looks like my approach is a quite a bit faster, so I'm posting it as my own answer. It's quite short!

from collections import Counter

def solution(seq):
    if not seq:     # special case for empty input sequence
        return 0
    counts = Counter(seq)
    return max(counts[x] + counts[x+1] for x in counts)

I suspect this is faster than Andrey's solution because the running time for both of our solutions really take O(n) + O(k) time where k is the number of distinct values in the input (and n is the total number of values in the input). My code handles the O(n) part very efficiently by handing off the sequence to the Counter constructor, which is implemented in C. It is likely to be a bit slower (on a per-item basis) to deal with the O(k) part, since it needs a generator expression. Andrey's code does the reverse (it runs slower Python code for the O(n) part, and uses faster builtin C functions for the O(k) part). Since k is always less than or equal to n (perhaps a lot less if the sequence has a lot of repeated values), my code is faster overall. Both solutions are still O(n) though, and both should be much better than sorting for large inputs.

1
  • That's a detailed analysis, and thanks again for the hint with Counter! Apr 1 '18 at 11:24

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