# The intersection of two sorted arrays

Given two sorted arrays: `A` and `B`. The size of array `A` is `La` and the size of array `B` is `Lb`. How to find the intersection of `A` and `B`?

If `La` is much bigger than `Lb`, then will there be any difference for the intersection finding algorithm?

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We are not going to do your homework for you –  shoosh Mar 8 '10 at 8:55
This is an interview question. –  user288609 Mar 8 '10 at 9:17
Do it's homework now, and in 5 years it'll become your colleague and you'll do it's work, or worse debug it's work. –  Guge Mar 8 '10 at 9:19
The text of the question looks like homework. Or do they do written interviews now? And if they do written interviews like this the interviews have become homework. –  Guge Mar 8 '10 at 9:20
Homework questions and interview questions are pretty much the same things. Either way, there's someone in authority who's expecting you to already know the answer, you're being judged on the response you give, and the assumption is that the response is your own. –  Rob Kennedy Mar 8 '10 at 9:30

Use `set_intersection` as here. The usual implementation would work similar to the merge part of merge-sort algorithm.

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I find it interesting that nobody has asked about the cost of comparing array elements. With an immediate data type (e.g. int or float), comparison is cheap and the set_intersection algorithm is fine. But if it is a complex data type where comparing two elements is expensive, I'd use a hashing technique instead. –  fearless_fool Oct 10 '12 at 18:08
@fearless_fool You are right. A related question: stackoverflow.com/questions/896155/… –  phaedrus Oct 13 '12 at 3:06

Since this looks like a HW...I'll give you the algorithm:

``````Let arr1,arr2 be the two sorted arrays of length La and Lb.
Let i be index into the array arr1.
Let j be index into the array arr2.
Initialize i and j to 0.

while(i < La and j < Lb) do

if(arr1[i] == arr2[j]) { // found a common element.
print arr[i] // print it.
increment i // move on.
increment j
}
else if(arr1[i] > arr2[j])
increment j // don't change i, move j.
else
increment i // don't change j, move i.
end while
``````
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I've been struggling with same problem for a while now, so far I came with:

1. Linear matching which will yield O(m+n) in worst case. You basically keep two pointers (A and B) each pointing to beginning of each array. Then advance pointer which points to smaller value, until you reach end of one of arrays, that would indicate no intersection. If at any point you have *A == *B - here comes your intersection.

2. Binary matching. Which yields ~ O(n*log(m)) in worst case. You basically pick smaller array and perform binary search in bigger array of all elements of the smaller array. If you want to be more fancy, you can even use last position where binary search failed and use it as starting point for next binary search. This way you marginally improve worst case but for some sets it might perform miracles :)

3. Double binary matching. It's a variation of regular binary matching. Basically you get element from the middle of smaller array and do binary search in bigger array. If you find nothing then you cut smaller array in half (and yes you can toss element you already used) and cut bigger array in half (use binary search failure point). And then repeat for each pair. Results are better than O(n*log(m)) but I am too lazy to calculate what they are.

Those are two most basic ones. Both have merits. Linear is a bit easier to implement. Binary one is arguably faster (although there are plenty of cases when linear matching will outperform binary).

If anyone knows anything better than that I would love to hear it. Matching arrays is what I do these days.

P.S. don't quote me on terms "linear matching" and "binary matching" as I made them up myself and there are probably fancy name for it already.

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You have figured it out correctly. –  nikhil Jun 25 '12 at 16:20
Galloping search is the right way to go here, not any of the things you mentioned. If you have a mismatch, advance the pointer pointing to the smaller thing by 1, then 2, then 4, and so forth until a mismatch is detected. Then binary search on the range you find that brackets the solution. –  tmyklebu Aug 26 '14 at 17:12
``````void Intersect()
{
int la, lb;
la = 5;
lb = 100;
int A[5];
int i, j, k;
i = j = k = 0;
for (; i < 5; ++i)
A[i] = i + 1;
int B[100];
for (; j < 100; ++j)
B[j] = j + 2;
int newSize = la < lb ? la : lb;
int* C = new int[newSize];
i = j = 0;
for (; k < lb && i < la && j < lb; ++k)
{
if (A[i] < B[j])
i++;
else if (A[i] > B[j])
j++;
else
{
C[k] = A[i];
i++;
j++;
}
}
for (k = 0; k < newSize; ++k)
cout << C[k] << NEWLINE;
}
``````
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`````` //intersection of two arrays
#include<iostream>
using namespace std;
int main() {

int i=0,j=0,m,n;
int arr1[i],arr2[j];
cout<<"Enter the number of elements in array 1: ";
cin>> m;
cout<<"Enter the number of elements in array 2: ";
cin>>n;
for (i=0;i<m;i++){
cin>> arr1[i];
}
for(j=0;j<n;j++){
cin>> arr2[j];
}
for(j=0;j<n;j++){
for(i=0;i<m;i++) {
if (arr1[i] == arr2[j]){
cout<< arr1[i];
cout << ' ';
break;
}
}
}

return 0;
}
``````
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