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Given an N arrays of size K each.. each of these K elements in the N arrays are sorted, each of these N*K elements are unique. Choose a single element from each of the N arrays, from the chosen subset of N elements. Subtract the minimum and maximum element. Now, this difference should be least possible Minimum.. Hope the problem is clear :) :)

Sample:

N=3, K=3

N=1 : 6, 16, 67
N=2 : 11,17,68
N=3 : 10, 15, 100

here if 16, 17, 15 are chosen.. we get the minimum difference as 17-15=2.

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2  
what have you tried so far? –  Manoj R May 23 '11 at 8:05
    
this is actually pretty difficult question for an interview, especially if it was a 30 or 45 min on site or phone interview. good for AMAZON :) –  zviadm May 25 '11 at 18:02
6  
You actually don't ask a question...I'm surprised everyone just assumed you wanted big O notation. –  Russell Asher Sep 4 '12 at 23:15
1  
What's the question? How to pick the right numbers which have a require constraint (i.e. their difference be the minimum possible?) –  Lorenzo Dematté Feb 28 '13 at 15:58

6 Answers 6

up vote 9 down vote accepted

I can think of O(N*K*N)(edited after correctly pointed out by zivo, not a good solution now :( ) solution.
1. Take N pointer initially pointing to initial element each of N arrays.

6, 16, 67
^ 
11,17,68
^
10, 15, 100
^ 

2. Find out the highest and lowest element among the current pointer O(k) (6 and 11) and find the difference between them.(5)
3. Increment the pointer which is pointing to lowest element by 1 in that array.

 6, 16, 67
    ^ 
 11,17,68
 ^
 10, 15, 100 (difference:5)
 ^ 

4. Keep repeating step 2 and 3 and store the minimum difference.

 6, 16, 67
    ^ 
 11,17,68
 ^
 10,15,100 (difference:5)
    ^ 


 6, 16, 67
    ^ 
 11,17,68
    ^
 10,15,100 (difference:2)
    ^ 

Above will be the required solution.

 6, 16, 67
    ^ 
 11,17,68
    ^
 10,15,100 (difference:84)
       ^ 

 6, 16, 67
        ^ 
 11,17,68
    ^
 10,15,100 (difference:83)
       ^ 

And so on......

EDIT:

Its complexity can be reduced by using a heap (as suggested by Uri). I thought of it but faced a problem: Each time an element is extracted from heap, its array number has to be found out in order to increment the corresponding pointer for that array. An efficient way to find array number can definitely reduce the complexity to O(K*N log(K*N)). One naive way is to use a data structure like this

Struct
{
    int element;
    int arraynumer;
}

and reconstruct the initial data like

 6|0,16|0,67|0

 11|1,17|1,68|1

 10|2,15|2,100|2

Initially keep the current max for first column and insert the pointed elements in heap. Now each time an element is extracted, its array number can be found out, pointer in that array is incremented , the newly pointed element can be compared to current max and max pointer can be adjusted accordingly.

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this is actually N*K*N solution. If i am not mistaken. because you chang pointers n*k times and each time you need O(N) operations –  zviadm May 25 '11 at 19:11
    
@zvio: Right!! Thanks for pointing it out. I overlooked it. –  Terminal May 25 '11 at 19:20
    
Maybe you can optimize to N*K*log(N), if you keep the N pointers in a heap, which will find the minimum element. The extract minimum, and insert new element are both log(N) operations. For the maximum element, you just need to keep which pointer is the maximum and compare it every time you advance a pointer. Nice solution. –  Uri May 25 '11 at 21:21
    
@Uri : thanks!! i have updated the solution. –  Terminal May 26 '11 at 7:09

Correctness proof for the accepted answer (Terminal's solution)

Assume that the algorithm finds a series A=<A[1],A[2],...,A[N]> which isn't the optimal solution (R).

Consider the index j in R, such that item R[j] is the first item among R that the algorithm examines and replaces it with the next item in its row.

Let A' denote the candidate solution at that phase (prior to the replacement). Since R[j]=A'[j] is the minimum value of A', it's also the minimum of R. Now, consider the maximum value of R, R[m]. If A'[m]<R[m], then R can be improved by replacing R[m] with A'[m], which contradicts the fact that R is optimal. Therefore, A'[m]=R[m]. In other words, R and A' share the same maximum and minimum, therefore they are equivalent. This completes the proof: if R is an optimal solution, then the algorithm is guaranteed to find a solution as good as R.

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for every element in 1st array

    choose the element in 2nd array that is closest to the element in 1st array
    current_array = 2;
    do
    {
        choose the element in current_array+1 that is closest to the element in current_array
        current_array++;
    } while(current_array < n);

complexity: O(k^2*n)

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This problem is for managers

You have 3 developers (N1), 3 testers (N2) and 3 DBAs (N3) Choose the less divergent team that can run a project successfully.

int[n] result;// where result[i] keeps the element from bucket N_i

int[n] latest;//where latest[i] keeps the latest element visited from bucket N_i

Iterate elements in (N_1 + N_2 + N_3) in sorted order
{
    Keep track of latest element visited from each bucket N_i by updating 'latest' array;

    if boundary(latest) < boundary(result)
    {
       result = latest;
    }
}

int boundary(int[] array)
{
   return Max(array) - Min(array);
}
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So here is an algorithm to do solve this problem in two steps:

First step is to merge all your arrays into one sorted array which would look like this:

combined_val[] - which holds all numbers
combined_ind[] - which holds index of which array did this number originally belonged to

this step can be done easily in O(K*N*log(N)) but i think you can do better than that too (maybe not, you can lookup variants of merge sort because they do step similar to that)

Now second step:

it is easier to just put code instead of explaining so here is the pseduocode:


int count[N] = { 0 }
int head = 0;
int diffcnt = 0;
// mindiff is initialized to overall maximum value - overall minimum value
int mindiff = combined_val[N * K - 1] - combined_val[0];
for (int i = 0; i < N * K; i++) 
{
  count[combined_ind[i]]++;

  if (count[combined_ind[i]] == 1) {
    // diffcnt counts how many arrays have at least one element between
    // indexes of "head" and "i". Once diffcnt reaches N it will stay N and
    // not increase anymore
    diffcnt++;
  } else {
    while (count[combined_ind[head]] > 1) {
      // We try to move head index as forward as possible while keeping diffcnt constant.
      // i.e. if count[combined_ind[head]] is 1, then if we would move head forward
      // diffcnt would decrease, that is something we dont want to do.
      count[combined_ind[head]]--;
      head++;
    }
  }

  if (diffcnt == N) {
    // i.e. we got at least one element from all arrays
    if (combined_val[i] - combined_val[head] < mindiff) {
      mindiff = combined_val[i] - combined_val[head];
      // if you want to save actual numbers too, you can save this (i.e. i and head
      // and then extract data from that)
    }
  }
}

the result is in mindiff.

The runing time of second step is O(N * K). This is because "head" index will move only N*K times maximum. so the inner loop does not make this quadratic, it is still linear.

So total algorithm running time is O(N * K * log(N)), however this is because of merging step, if you can come up with better merging step you can probably bring it down to O(N * K).

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Hey.. you have forgotten to add the snippet for mindiff initialization.. I also think I understood but am not very clear. could you also add a small comment in your code, especially in the head++ –  Manjunath Manohar May 25 '11 at 18:25
    
mindiff is initialized to largest possible value which is overall maximum number - overall minimum number. Main point of this algorithm is to find minimum and maximum values. Index "i" points to maximum value. Index "head" points to minimum value. Every time we increase "i" we try to move index "head" as farther as possible while we still keep at least one element from every array. –  zviadm May 25 '11 at 18:44
    
This is a briliant solution. Your comment about my algorithm being false is in place. I don't think you can do better than O(N*K*log(N)), at least not in the worse case, at least not the 'N' parts, otherwise, in the special case of K=1 you'll be able to sort an array in a time better than N*Log(N) –  Uri May 25 '11 at 18:49
    
Thanks @Uri. Your observation makes sense about the merge step. Thus merging arrays truly takes O(N * K * log(N)) in worst case scenario. –  zviadm May 25 '11 at 18:55

I've O(K*N*log(K)), with typical execution much less. Currently cannot think anything better. I'll explain first the easier to describe (somewhat longer execution):

  1. For each element f in the first array (loop through K elements)
  2. For each array, starting from the second array (loop through N-1 arrays)
  3. Do a binary search on the array, and find element closest to f. This is your element (Log(K))

This algorithm can be optimized, if for each array, you add a new Floor Index. When performent the binary search, search between 'Floor' to 'K-1'. Initially Floor index is 0, and for first element you search through the entire arrays. Once you find an element closest to 'f', update the Floor Index with the index of that element. Worse case is the same (Floor may not update, if maximum element of first array is smaller than any other minimum), but average case will improve.

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Hey Nice solution, I was thinking of working on a solution that uses min heap and a max heap.. any suggestions on that –  Manjunath Manohar May 23 '11 at 8:22
    
this algorithm is not complete or correct. Lets say you chose 10 from N=1. (first array) N=2: 1 15 N=3: 5 16 you will choose 15 and 5 so your difference is 10, but if you chose 15 and 16 your difference would be 6. –  zviadm May 25 '11 at 17:01
    
@zviadm Same solution I came up with in ~10 seconds after looking at the problem, and immediately I started wondering if it is correct... still, I think it is heading in the right direction –  Lorenzo Dematté Feb 28 '13 at 16:06
    
solution is correct. only find the ceil and floor of minimum element found so far. and keep the one which is closer to the minimum. 1. take first element from first array and consider it as minimum. 2. find ceil and floor of minimum in second array and choose the one which is closer to minimum. 3. update the minimum 4. search in subsequent rows. 5.do this for all elemnts of row1 –  shivi Jan 4 at 4:41

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