# Find the top k sums of two sorted arrays

You are given two sorted arrays, of sizes n and m respectively. Your task (should you choose to accept it), is to output the largest k sums of the form a[i]+b[j].

A O(k log k) solution can be found here. There are rumors of a O(k) or O(n) solution. Does one exist?

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The problem in the link you gave is top n values of A[i] + B[j], A,B are sorted arrays of length n. That need not be the case as stated in this question. In fact in that thread James Fingas (see page 2) has given an O(n) time algorithm (for k=n I believe). +1 anyway. – Aryabhatta Feb 15 '11 at 7:10
@Moron - sorry, confused this with a similar question. I edited this one. Are you sure James' solution is valid? – ripper234 Feb 15 '11 at 7:17
@ripper: No, I am not sure, but others on that thread seem to confirm the correctness. Just pointed that out, in case you missed it. You read it and found it lacking? – Aryabhatta Feb 15 '11 at 7:23
@Moron - there are a few solutions that claim to be O(n) in that thread, but none that are both correct and have a really concise explanation, one that I would read and say "ah-ha, now I understand!" – ripper234 Feb 15 '11 at 7:25
@ripper: I was a regular at that forum for a few years and I am pretty sure James Fingas was one of the better/saner puzzle solvers there (he was a regular before I frequented it). Of course, I never did make the effort to understand that solution, but given that Hippo (and I believe Grimbal) agree, I would be reasonably confident of the correctness. Of course, that is not proof. – Aryabhatta Feb 15 '11 at 7:29

I found the responses at your link mostly vague and poorly structured. Here's a start with a O(k * log(min(m, n))) O(k * log(m + n)) algorithm.

Suppose they are sorted decreasing. Imagine you computed the m*n matrix of the sums as follows:

for i from 0 to m
for j from 0 to n
sums[i][j] = a[i] + b[j]


In this matrix, values monotonically decrease down and to the right. With that in mind, here is an algorithm which performs a graph search through this matrix in order of decreasing sums.

q : priority queue (decreasing) := empty priority queue
add (0, 0) to q with priority a[0] + b[0]
while k > 0:
k--
x := pop q
output x
(i, j) : tuple of int,int := position of x
if i < m:
add (i + 1, j) to q with priority a[i + 1] + b[j]
if j < n:
add (i, j + 1) to q with priority a[i] + b[j + 1]


Analysis:

1. The loop is executed k times.
1. There is one pop operation per iteration.
2. There are up to two insert operations per iteration.
2. The maximum size of the priority queue is O(min(m, n)) O(m + n).
3. The priority queue can be implemented with a binary heap giving log(size) pop and insert.
4. Therefore this algorithm is O(k * log(min(m, n))) O(k * log(m + n)).

Note that the general priority queue abstract data type needs to be modified to ignore duplicate entries. Alternately, you could maintain a separate set structure that first checks for membership in the set before adding to the queue, and removes from the set after popping from the queue. Neither of these ideas would worsen the time or space complexity.

I could write this up in Java if there's any interest.

Edit: fixed complexity. There is an algorithm which has the complexity I described, but it is slightly different from this one. You would have to take care to avoid adding certain nodes. My simple solution adds many nodes to the queue prematurely.

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This is O(mn) (creation of sum matrix takes O(mn) OP want's at most O(n + m + k) – Saeed Amiri Feb 15 '11 at 8:38
@Saeed, thanks, but I'm not actually creating that matrix. I'm just describing how I'm imagining the problem. If you see a problem in the analysis I provided, please point it out. – rlibby Feb 15 '11 at 8:41
Yes, this is an elegant solution. The complexity is actually O(k * log min(k, m, n)) - if k < m, n then the priority queue will only have k elements. Now, I'd like to see a a better solution in terms of complexity. – ripper234 Feb 15 '11 at 9:25
@ripper234, you would be correct if I had got the queue size bound right, but unfortunately I think it's actually O(m + n) as I wrote it rather than O(min(m, n)). It can be made O(min(m, n)) but it requires slightly more work. – rlibby Feb 15 '11 at 15:35
I can see how this could be improved on but I've yet to nail down the details. – biziclop Feb 15 '11 at 16:28
private static class FrontierElem implements Comparable<FrontierElem> {
int value;
int aIdx;
int bIdx;

public FrontierElem(int value, int aIdx, int bIdx) {
this.value = value;
this.aIdx = aIdx;
this.bIdx = bIdx;
}

@Override
public int compareTo(FrontierElem o) {
return o.value - value;
}

}

public static void findMaxSum( int [] a, int [] b, int k ) {
Integer [] frontierA = new Integer[ a.length ];
Integer [] frontierB = new Integer[ b.length ];
PriorityQueue<FrontierElem> q = new PriorityQueue<MaxSum.FrontierElem>();
frontierA[0] = frontierB[0]=0;
q.add( new FrontierElem( a[0]+b[0], 0, 0));
while( k > 0 ) {
FrontierElem f = q.poll();
System.out.println( f.value+"    "+q.size() );
k--;
frontierA[ f.aIdx ] = frontierB[ f.bIdx ] = null;
int fRight = f.aIdx+1;
int fDown = f.bIdx+1;
if( fRight < a.length && frontierA[ fRight ] == null ) {
q.add( new FrontierElem( a[fRight]+b[f.bIdx], fRight, f.bIdx));
frontierA[ fRight ] = f.bIdx;
frontierB[ f.bIdx ] = fRight;
}
if( fDown < b.length && frontierB[ fDown ] == null ) {
q.add( new FrontierElem( a[f.aIdx]+b[fDown], f.aIdx, fDown));
frontierA[ f.aIdx ] = fDown;
frontierB[ fDown ] = f.aIdx;
}
}
}


The idea is similar to the other solution, but with the observation that as you add to your result set from the matrix, at every step the next element in our set can only come from where the current set is concave. I called these elements frontier elements and I keep track of their position in two arrays and their values in a priority queue. This helps keep the queue size down, but by how much I've yet to figure out. It seems to be about sqrt( k ) but I'm not entirely sure about that.

(Of course the frontierA/B arrays could be simple boolean arrays, but this way they fully define my result set, This isn't used anywhere in this example but might be useful otherwise.)

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I'm sorry I don't have time to read it in detail yet, but you should be able to do it with just one array tracking frontiers. Choose the one with minimum length. That should bring you to O(min(m, n) max size for the array and O(k * log(min(k, m, n))) time for the algorithm. I'll take another look within a day. – rlibby Feb 15 '11 at 21:11
@rlibby I guess you could, but this way a frontier lookup is just O(1) time whichever axis you're interested in. – biziclop Feb 15 '11 at 21:20
The concaveness insight is really nice, but I don't see how it improves worst case space complexity. When the covered part of the matrix takes the form of 1-sized steps, then the candidate set is O(n+m), right? – Eyal Schneider Jan 6 '14 at 22:17