27

Given an array of Integers, and a range (low, high), find all contiguous subsequence in the array which have sum in the range.

Is there a solution better than O(n^2)?

I tried a lot but couldn't find a solution that does better than O(n^2). Please help me find a better solution or confirm that this is the best we can do.

This is what I have right now, I'm assuming the range to be defined as [lo, hi].

public static int numOfCombinations(final int[] data, final int lo, final int hi, int beg, int end) {
    int count = 0, sum = data[beg];

    while (beg < data.length && end < data.length) {
       if (sum > hi) {
          break;
       } else {
          if (lo <= sum && sum <= hi) {
            System.out.println("Range found: [" + beg + ", " + end + "]");
            ++count;
          }
          ++end;
          if (end < data.length) {
             sum += data[end];
          }
       }
    }
    return count;
}

public static int numOfCombinations(final int[] data, final int lo, final int hi) {
    int count = 0;

    for (int i = 0; i < data.length; ++i) {
        count += numOfCombinations(data, lo, hi, i, i);
    }

    return count;
}
11
  • Does sum > hi .. break assume that integers are non-negative? (Otherwise, why to break if the sum can decrease as we continue.)
    – AlexD
    Commented Jul 3, 2014 at 1:50
  • 4
    Given an array of all zeroes and the range (-1, 1), there are O(n^2) solutions, and you clearly require O(n^2) time just to print the answers. Commented Jul 3, 2014 at 2:36
  • 2
    @RaymondChen I think in his code, he only return count ?
    – Pham Trung
    Commented Jul 3, 2014 at 2:42
  • 1
    Can all integers only be positive? or can be positive or negative?
    – notbad
    Commented Jul 3, 2014 at 3:08
  • 1
    @notbad integers can be positive or negative Commented Jul 3, 2014 at 16:27

7 Answers 7

18

O(n) time solution:

You can extend the 'two pointer' idea for the 'exact' version of the problem. We will maintain variables a and b such that all intervals on the form xs[i,a), xs[i,a+1), ..., xs[i,b-1) have a sum in the sought after range [lo, hi].

a, b = 0, 0
for i in range(n):
    while a != (n+1) and sum(xs[i:a]) < lo:
        a += 1
    while b != (n+1) and sum(xs[i:b]) <= hi:
        b += 1
    for j in range(a, b):
        print(xs[i:j])

This is actually O(n^2) because of the sum, but we can easily fix that by first calculating the prefix sums ps such that ps[i] = sum(xs[:i]). Then sum(xs[i:j]) is simply ps[j]-ps[i].

Here is an example of running the above code on [2, 5, 1, 1, 2, 2, 3, 4, 8, 2] with [lo, hi] = [3, 6]:

[5]
[5, 1]
[1, 1, 2]
[1, 1, 2, 2]
[1, 2]
[1, 2, 2]
[2, 2]
[2, 3]
[3]
[4]

This runs in time O(n + t), where t is the size of the output. As some have noticed, the output can be as large as t = n^2, namely if all contiguous subsequences are matched.

If we allow writing the output in a compressed format (output pairs a,b of which all subsequences are contiguous) we can get a pure O(n) time algorithm.

4
  • 1
    I think it is actually possible to solve it even with O(1) space. Instead of computing an array of prefix sum, we can maintain only two sums, sum(xs[i:a]) and sum(xs[i:b]). When the start position moves, i.e. i increments, just subtract the the value from the two sums.
    – wlnirvana
    Commented Sep 10, 2016 at 18:13
  • @RameshwarBhaskaran Unfortunately yes. With negative numbers we no longer have that the sequence is guaranteed to increase with b and decrease with a. Commented Nov 2, 2016 at 12:56
  • 1
    Can you explain the intuition behind this solution?
    – Huey
    Commented Aug 1, 2017 at 0:11
  • Will not work with negative and zero numbers. Ex : {5, 10, 2, 3, 5, -5} for range [15, 20]. Sum of all elements in array equals to 20 but will not get captured by your algo. You algorithm will work fine with positive integers though. Commented Sep 9, 2020 at 13:26
8

Starting from this problem: find all contiguous sub-sequences that sum to x. What we need is something similar.

For every index i, we can calculate the sum of the segment from 0 to i, which is x. So, the problem now is we need to find from 0 to i - 1, how many segments have sum from (x - low) to (x - high), and it should be faster than O(n). So there are several data structures help you to do that in O(logn), which are Fenwick tree and Interval tree.

So what we need to do is:

  • Iterating through all index from 0 to n (n is the size of the array).

  • At index ith, calculate, starting from 0 to ith index, the sum x, query the tree to get the total occurrences of numbers fall in the range (x - high, x - low).

  • Add x to the tree.

So the time complexity will be O(n log n)

2
  • An interval tree and a segment tree are two different things. Commented Jul 9, 2016 at 21:56
  • 1
    An interval tree is not what you think it is. The data structures that support the operation you desire are Fenwick trees and Segment trees. Commented Jul 21, 2016 at 16:57
5

You should use a simple dynamic programming and binary search. To find the count:

    from bisect import bisect_left, bisect_right

    def solve(A, start, end):
        """
        O(n lg n) Binary Search
        Bound:
        f[i] - f[j] = start
        f[i] - f[j'] = end
        start < end
        f[j] > f[j']

        :param A: an integer array
        :param start: lower bound
        :param end: upper bound 
        :return:
        """
        n = len(A)
        cnt = 0
        f = [0 for _ in xrange(n+1)]

        for i in xrange(1, n+1):
            f[i] = f[i-1]+A[i-1]  # sum from left

        f.sort()
        for i in xrange(n+1):
            lo = bisect_left(f, f[i]-end, 0, i)
            hi = bisect_right(f, f[i]-start, 0, i)
            cnt += hi-lo

        return cnt

https://github.com/algorhythms/LintCode/blob/master/Subarray%20Sum%20II.py

To find the results rather the count, you just need another hash table to store the mapping from original (not sorted) f[i] -> list of indexes.

Cheers.

5
  • Good solution! just f might not need to sort
    – spiralmoon
    Commented Jul 12, 2015 at 1:36
  • It the array contains negative number, f need to be sorted.
    – Daniel
    Commented Jan 11, 2016 at 4:28
  • @ThinkRecursively if the array includes non-negative numbers, you just the sum array is monotone, and doesn't need sorting for binary search to work, but if it includes negative numbers, the value might drop and it is not monotone, so you need to sort, but I'm not sure that whether the rest of algorithm works for negative numbers or not.
    – FazeL
    Commented Jan 11, 2016 at 10:10
  • 1
    It doesnt work when array contains negative numbers. For example consider [2,-1] with low=-1 and high=0. There is one subsequence (1,1) with sum -1 but the above algorithm will return 0.
    – Satvik
    Commented Jan 30, 2016 at 11:32
  • @Satvik if the algorithm does not work with negative numbers. Why the sort is needed?
    – Daniele
    Commented Jul 4, 2016 at 13:28
0

Here is way you can get O(nlogn) if there are only positive numbers :-

1. Evaluate cumulative sum of array
2. for i  find total sum[j] in (sum[i]+low,sum[i]+high) using binary search
3. Total = Total + count
4. do 3 to 5 for all i

Time complexity:-

Cumulative sum is O(N)
Finding sums in range is O(logN) using binary search
Total Time complexity is O(NlogN)
2
  • Binary search? the cumulative sum may not be in sorted order?
    – Pham Trung
    Commented Jul 3, 2014 at 6:30
  • @PhamTrung it is only for positive integers please check Commented Jul 3, 2014 at 6:32
0

If all integers are non-negative, then it can be done in O(max(size-of-input,size-of-output)) time. This is optimal.

Here's the algorithm in C.

void interview_question (int* a, int N, int lo, int hi)
{
  int sum_bottom_low = 0, sum_bottom_high = 0,
      bottom_low = 0, bottom_high = 0,
      top = 0;
  int i;

  if (lo == 0) printf ("[0 0) ");
  while (top < N)
  {
    sum_bottom_low += a[top];
    sum_bottom_high += a[top];
    top++;
    while (sum_bottom_high >= lo && bottom_high <= top)
    {
      sum_bottom_high -= a[bottom_high++];
    }
    while (sum_bottom_low > hi && bottom_low <= bottom_high)
    {
      sum_bottom_low -= a[bottom_low++];
    }
    // print output
    for (i = bottom_low; i < bottom_high; ++i)
      printf ("[%d %d) ", i, top);
  }
  printf("\n");
}

Except for the last loop marked "print output", each operation is executed O(N) times; the last loop is executed once for each interval printed. If we only need to count the intervals and not print them, the entire algorithm becomes O(N).

If negative numbers are allowed, then O(N^2) is hard to beat (might be impossible).

0
yes in my opinion it can be in O(n)

struct subsequence
{
int first,last,sum;
}s;

function(array,low,high)
{
int till_max=0;
s.first=0;s.last=0;s.sum=0;
for(i=low;i<high;i++)
{

if(till_max+array[i]>array[i])
{
s.first=s.first;
s.last=i;
till_max+=array[i];
}
else
{
s.first=i;
s.last=i;
till_max=array[i];
}
if(till_max in range)
{
s.sum=till_max;
   printf("print values between first=%d and last=%d and sum=%d",s.first,s.last,s.sum);
}
}
}
0

O(NlogN) with simple data structures is sufficient.

For contiguous subsequences, I think it means for subarrays.

We maintain a prefix sum list, prefix[i] = sum for the first i elements. How to check if there exists a range rum between [low, high]? We can use binary search. So,

prefix[0] = array[0]  
for i in range(1, N) 
  prefix[i] = array[i] + prefix[i-1];
  idx1 = binarySearch(prefix, prefix[i] - low);
  if (idx1 < 0) idx1 = -1 - idx1;
  idx2 = binarySearch(prefix, prefix[i] - high);
  if (idx2 < 0) idx2 = -1 - idx2;
  // for any k between [idx1, idx2], range [k, i] is within range [low, high]
  insert(prefix, prefix[i])

The only thing we need to care is we also need to insert new values, thus any array or linked list is NOT okay. We can use a TreeSet, or implement your own AVL trees, both binary search and insertion would be in O(logN).

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