I'm working on an interview question for which I couldn't find any textbook solution for. Given a list of integers, find the maximum sum of any consecutive values / sublist no longer than a given K length.

  • Did you try anything so far to solve your problem? Show your effort first so people might show theirs. Please read How to Ask and help center as a start. – idstam Mar 13 '15 at 5:17
  • algo or code? .. – Dinesh Mar 13 '15 at 5:18
  • @idstam I've tried 2 variations of a quadratic solution but I'm hoping to find a linear time solution. – rtheunissen Mar 13 '15 at 6:44

Let p[i] be the prefix sum a[0] + ... + a[i - 1]. We can compute the sequence p easily in linear time. For a fixed index i, the maximum sum of a subarray of size at most K that has its right boundary at index i can be computed as

MAX(j = max(0, i - K + 1) to i, p[i + 1] - p[j]) = p[i + 1] - MIN(j = max(0, i - K + 1) to i, p[j])

We can process the possible right borders i in ascending order. We then want to compute for each such i the MIN term in the above formula in O(1). This is exactly the sliding window minimum problem, which has a nice solution using a special queue data structure. This queue supports the operations push/pop as well as min in amortized O(1). Using it, our algorithm looks like this:

q = new MinQueue()
sum = 0
answer = 0
for i := 0 to N - 1:
    q.push(sum)  # sum == p[i]
    if len(q) > K:
    sum += a[i]
    answer = max(answer, sum - q.min())  # sum == p[i + 1]

The total runtime is linear.

  • Hi @Niklas, I've implemented your solution here: repl.it/dw8/1, even though the queue does not have O(1) min. The expected answer is 9, why is it giving 10? Did I get something wrong somewhere? – rtheunissen Mar 14 '15 at 3:00
  • @paranoid-android You are using pop() on a deque, which pops from the right. You should use popleft() instead. FWIW, here's an implementation of the min-queue in C++: github.com/niklasb/contest-algos/blob/master/… – Niklas B. Mar 14 '15 at 9:31
  • This is very informative thank you very much. However, it doesn't currently catch the case where all values in the list are negative. – rtheunissen Mar 15 '15 at 1:43
  • @paranoid-android Why not? The answer should be 0 in that case no? If not, just initialize answer to negative infinity – Niklas B. Mar 15 '15 at 11:00
  • 1
    @paranoid-android It's certainly a matter of definition. I consider the empty subarray as optimal in this case, with sum 0. – Niklas B. Mar 15 '15 at 22:03

It looks similar to maximum subarray problem. refer _http://en.wikipedia.org/wiki/Maximum_subarray_problem_

var arr = [1,2,31,24,34,3,23,24,3,25,34,54,3,2,34];
var getSmallestSubSeqSum = function(arr, k){
    var totalLength = arr.length, index = 0, sums= [];
    for(index=0;index < totalLength-k+1;index++)

    for(var index=0; index < totalLength-k+1;index++)
        for(var aI = 0; aI < k; aI++)
            sums[index] += arr[index + aI];
    console.log('Total Length: ' + totalLength);
    console.log('Sub Length: ' + 3);    
    console.log('sums length: ' + sums.length);
    console.log("Array: "+arr);

    index = Math.max.apply(Math, sums);
    console.log('Max Sum: ' + index);
    console.log("Sums: "+ sums);

    index = sums.indexOf(index);
    console.log("max sum sub array: " + arr.slice(index, index + k));

getSmallestSubSeqSum(arr, 6);

The above code snippet should help this is javascript.

  • this is rather inefficient in computing sum[index]. Please see my answer at bottom – Dinesh Mar 13 '15 at 18:19

The N numbers are X[0],...X[N-1] and assuming 1<=K<=N. S[i,l] stands for the maximum sum of the sublist that starts from i and has no more than l length.

You have S[i,1] = X[i] and then S[i,l] = MAX(S[i+1, l-1]+X[i], X[i]), where l>=2.

The final answer is MAX(S[i,K], where i<=N-1 and i>=0).

  • That's Omega(NK) however, although linear time is possible – Niklas B. Mar 13 '15 at 10:54

Here is an outline. You have X[i, where i=1..N] numbers. Given K, assuming K <= N, there are N-K+1 sub-sequences, starting from 1..(N-K+1). You can store the sums in S[j, j=1..N-K+1]

Say, you already have S[j]. Then S[j+1] = S[j] - X[j-1] + X[j+K-1]. You need to find S[1], and then the rest are simple. The problem now reduces to finding the largest value in S. There can be 1 or more answers. Complexity linear.

HTH get you started.

  • Actually the solution might be a subarray smaller than K – Niklas B. Mar 13 '15 at 10:51
  • E.g. K = 2, a = [-1, -1, 1, -1] – Niklas B. Mar 13 '15 at 11:41
  • Indeed, but my understanding is that K must be observed. – Dinesh Mar 13 '15 at 18:16
  • ..continuing..Otherwise (and that's a very interesting problem, thank you), generalizing your hunt for negatives at ends -- the largest sub-subsequence at either ends that results in a -ve sum could be discarded and process repeated (for each subsequence) until there was no more discards (wondering if a single discard will suffice - any thoughts?) – Dinesh Mar 13 '15 at 18:23
  • quote: "no longer than a given K" The greedy approach you describe is obviously correct, but it doesn't yield a fast algorithm – Niklas B. Mar 13 '15 at 21:44

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