# Find the pair across 2 arrays with kth largest sum [closed]

Given two sorted arrays of numbers, we want to find the pair with the kth largest possible sum. (A pair is one element from the first array and one element from the second array). For example, with arrays

• [2, 3, 5, 8, 13]
• [4, 8, 12, 16]

The pairs with largest sums are

• 13 + 16 = 29
• 13 + 12 = 25
• 8 + 16 = 24
• 13 + 8 = 21
• 8 + 12 = 20

So the pair with the 4th largest sum is (13, 8). How to find the pair with the kth largest possible sum?

I am looking for a solution involving either a min heap or a max heap.

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## closed as not a real question by Jacob, Tichodroma, Aziz Shaikh, Sergey K., kapaSep 26 '12 at 7:43

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That can be easily done in `O(k*logk)`. I'll only assume arrays are sorted in descending order, to simplify notation.

The idea is simple. We'll find 1st, 2nd, .., k-th maximum values one by one. But to even consider pair `(i, j)` we need to have both `(i-1, j)` and `(i, j-1)` already selected, because they both are greater or equal than `(i, j)`.

It's much like if we push all `n*m` pairs into the heap and then remove max `k` times. Only we don't need all `n*m` pairs.

``````heap.add(pair(0, 0));  // biggest pair

// remove max k-1 times
for (int i = 0; i < k - 1; ++i) {
// get max and remove it from the heap
max = heap.popMax();

// add next candidates
heap.add(pair(max.i + 1, max.j));
heap.add(pair(max.i, max.j + 1));
}

// get k-th maximum element
max = heap.popMax();
maxVal = a[max.i] + b[max.j];
``````

Some things to consider.

• Duplicated pairs can be added to the heap, this can be prevented with hash.
• Indexes need to be validated, e.g. that `max.i + 1 < a.length`.
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@Nikita: thanks for the effort! I was wondering why do you not consider i+1 and the biggest element in the second array?. I mean why do max.i+1 , max.j, instead of max.i+1 and the first element in the second array. – TimeToCodeTheRoad Mar 7 '11 at 8:32
@TimeToCodeTheRoad (i+1, 0) was already added to the heap when we processed (i, 0). And we already processed (i, 0) because `a[i]+b[0] >= a[i] + b[j]` (Well, we might not have, if they are equal, but you can see that it changes nothing in terms of correctness.) – Nikita Rybak Mar 7 '11 at 8:43
@Nikita: Thanks again! also, why dont we consider the first element of array A and j+1 element of the second array? I really appreciate your help. Pls help me – TimeToCodeTheRoad Mar 7 '11 at 8:45
@Nikita: I want to award you more points than just selecting ur answer. Is there any way? :) – TimeToCodeTheRoad Mar 7 '11 at 8:55
@TimeToCodeTheRoad It's the same situation as in your first comment, only i and j switched. Same reasoning applies. – Nikita Rybak Mar 7 '11 at 9:17

I understand you want a heap but that isn't the most efficient solution, as phimuemue pointed out.

You can max_heap both arrays, and set an iterator at the root for both. At this point, you have the largest sum.

Now, at each step, find the maximum, unvisited node among the children and neighbors of both pointers -- this is the next largest sum. Move the pointer in the corresponding heap there.

Repeat k times.

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Is the statement "at each step, take the pointer to the smaller of the two values and traverse it to the maximum of its children and neighbors" really sound? Take this for example, heap1 [7, 1, 2], heap2 [8, 6, 7]. Without doubt the lagest sum is 7(from heap1) + 8(from heap2). But the second lagest is 7(from heap1) + 7(from heap2) instead of 2(from heap1) + 8(from heap2). Regards! – Summer_More_More_Tea Mar 7 '11 at 1:15
Ah, you're right. Edited my answer – Vanwaril Mar 7 '11 at 1:25

Here is my answer, I think it's working well, but could someone tell me what's its complexity ?

Thanks

``````int ksum( int a[], int n, int b[], int m, int maxk )
{

std::vector<int> results;
int* check = new int[m*n];
memset( check, 0, n*m*sizeof(int) );

int finali, finalj;
int starti = 0, startj = 0;
for( int k=1; k<maxk+1; ++k )
{
int max = 0;
int maxi=n, maxj=m;
for( int i=starti; i<n && i<k; ++i )
{
if( i>maxj )
break;
for( int j=i; j<m && j<k; ++j )
{
if( i>maxi && j>=maxj )
break;
if( check[i*m+j] == 0 )
{
int tmp = a[i]+b[j];
if( tmp>max )
{
max = tmp;
finali = i, finalj = j;
}
maxi = i, maxj = j;
break;
}
}
}
starti = finali;

maxi=n, maxj=m;
for( int j=startj; j<n && j<k; ++j )
{
if( j>maxi )
break;
for( int i=j; i<m && i<k; ++i )
{
if( j>maxj && i>=maxi )
break;
if( check[i*m+j] == 0 )
{
int tmp = a[i]+b[j];
if( tmp>max )
{
max = tmp;
finali = i, finalj = j;
}
maxi = i, maxj = j;
break;
}
}
}
startj = finalj;

if( max > 0 )
{
check[finali*m+finalj] = 1;
results.push_back( max );
}
}

delete[] check;
if( maxk > results.size() )
return 0;
else
return results[maxk-1];
}

int _tmain(int argc, _TCHAR* argv[])
{
int a[] = {10,8,6,4,1};
int b[] = {9,6,3,2,1};
int res = ksum( a, 5, b, 5, 9 );
return 0;
}
``````
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