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Given an array of size n and k, how do you find the maximum for every contiguous subarray of size k?

For example

arr = 1 5 2 6 3 1 24 7
k = 3
ans = 5 6 6 6 24 24

I was thinking of having an array of size k and each step evict the last element out and add the new element and find maximum among that. It leads to a running time of O(nk). Is there a better way to do this?

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2  
This question is closely related to this earlier one: stackoverflow.com/questions/8499227/… –  templatetypedef Jun 22 '13 at 18:28

10 Answers 10

up vote 5 down vote accepted

You need a fast data structure that can add, remove and query for the max element in less than O(n) time (you can just use an array if O(n) or O(nlogn) is acceptable). You can use a heap, a balanced binary search tree, a skip list, or any other sorted data structure that performs these operations in O(log(n)).

The good news is that most popular languages have a sorted data structure implemented that supports these operations for you. C++ has std::set and std::multiset (you probably need the latter) and Java has TreeSet.

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Using a heap (or tree), you should be able to do it in O(n * log(k)). I'm not sure if this would be indeed better.

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Compare the first k elements and find the max, this is your first number

then compare the next element to the previous max. If the next element is bigger, that is your max of the next subarray, if its equal or smaller, the max for that sub array is the same

then move on to the next number

max(1 5 2) = 5
max(5 6) = 6
max(6 6) = 6
... and so on
max(3 24) = 24
max(24 7) = 24

It's only slightly better than your answer

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You just forgot that the biggest number of the current window might get out of the window when it slides... –  leo Nov 7 '11 at 1:56
    
oh yeah my answer is wrong. ignore mine –  Clay Goddard Nov 7 '11 at 2:02

Just notice that you only have to find in the new window if: * The new element in the window is smaller than the previous one (if it's bigger, it's for sure this one). OR * The element that just popped out of the window was the current bigger.

In this case, re-scan the window.

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An O(n) time solution is possible by combining the two classic interview questions:

  • Make a stack data-structure (called MaxStack) which supports push, pop and max in O(1) time.

    This can be done using two stacks, the second one contains the minimum seen so far.

  • Model a queue with a stack.

    This can done using two stacks. Enqueues go into one stack, and dequeues come from the other.

For this problem, we basically need a queue, which supports enqueue, dequeue and max in O(1) (amortized) time.

We combine the above two, by modelling a queue with two MaxStacks.

To solve the question, we queue k elements, query the max, dequeue, enqueue k+1 th element, query the max etc. This will give you the max for every k sized sub-array.

I believe there are other solutions too.

1)

I believe the queue idea can be simplified. We maintain a queue and a max for every k. We enqueue a new element, and dequeu all elements which are not greater than the new element.

2) Maintain two new arrays which maintain the running max for each block of k, one array for one direction (left to right/right to left).

3) Use a hammer: Preprocess in O(n) time for range maximum queries.

The 1) solution above might be the most optimal.

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+1. The fastest solution. –  Ivan Benko Nov 7 '11 at 7:57

You have heard about doing it in O(n) using dequeue.

Well that is well known algorithm for this question to do in O(n).

but the method i am telling is quite Simple and requires Dynamic Programming and have time complexity O(n).

Your Sample Input:
n=10 , W = 3

10 3
1 -2 5 6 0 9 8 -1 2 0

Answer = 5 6 6 9 9 9 8 2

Concept: Dynamic Programming

Algorithm:

  1. N is number of elements in an array and W is window size . So, Window number = N-W+1
  2. Now divide array into block of W starting from index 1.

    here divide into block of size 'W'=3. For your sample input:

    divided blocks

  3. Why we divided in block because we will calculate maximum in 2 ways A.) by traversing from left to right B.) by traversing from right to left. but how ??

  4. Firstly, Traversing from Left to Right. For each element ai in block we will find maximum till that element ai starting from START of Block to END of that block. so Here,

    LR

  5. Secondly, Traversing from Right to Left. For each element 'ai' in block we will find maximum till that element 'ai' starting from END of Block to START of that block. so Here,

    RL

  6. Now we have to do is find maximum for each subarray or window of size 'W'. so, starting from index = 1 to index = N-W+1 .

    max_val[index] = max(RL[index], LR[index+w-1]);

    LR + RL

     for index=1: max_val[1] = max(RL[1],LR[3]) = max(5,5)= 5
    

Simliarly, for all index i, (i<=(n-k+1)), value at RL[i] and LR[i+w-1] are compared and maximum among those two is answer for that subarray.

So Final Answer : 5 6 6 9 9 9 8 2

Time Complexity: O(n)

Implementation code:

// Shashank Jain
#include <iostream>
#include <cstdio>
#include <cstring>
#include <algorithm>

#define LIM 100001 

using namespace std;

int arr[LIM]; // Input Array
int LR[LIM]; // maximum from Left to Right
int RL[LIM]; // maximum from Right to left
int max_val[LIM]; // number of subarrays(windows) will be n-k+1

int main(){
    int n, w, i, k; // 'n' is number of elements in array
                    // 'w' is Window's Size 
    cin >> n >> w;

    k = n - w + 1; // 'K' is number of Windows

    for(i = 1; i <= n; i++)
        cin >> arr[i];

    for(i = 1; i <= n; i++){ // for maximum Left to Right
        if(i % w == 1) // that means START of a block
            LR[i] = arr[i];
        else
            LR[i] = max(LR[i - 1], arr[i]);        
    }

    for(i = n; i >= 1; i--){ // for maximum Right to Left
        if(i == n) // Maybe the last block is not of size 'W'. 
            RL[i] = arr[i]; 
        else if(i % w == 0) // that means END of a block
            RL[i] = arr[i];
        else
            RL[i] = max(RL[i+1], arr[i]);
    }

    for(i = 1; i <= k; i++)    // maximum
        max_val[i] = max(RL[i], LR[i + w - 1]);

    for(i = 1; i <= k ; i++)
        cout << max_val[i] << " ";

    cout << endl;

    return 0;
}  

Running Code Link


I'll try to proof: (by @johnchen902)

If k % w != 1 (k is not the begin of a block)

Let k* = The begin of block containing k
ans[k] = max( arr[k], arr[k + 1], arr[k + 2], ..., arr[k + w - 1])
       = max( max( arr[k],  arr[k + 1],  arr[k + 2],  ..., arr[k*]), 
              max( arr[k*], arr[k* + 1], arr[k* + 2], ..., arr[k + w - 1]) )
       = max( RL[k], LR[k+w-1] )

Otherwise (k is the begin of a block)

ans[k] = max( arr[k], arr[k + 1], arr[k + 2], ..., arr[k + w - 1])
       = RL[k] = LR[k+w-1]
       = max( RL[k], LR[k+w-1] )
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1  
Why does it work ? Give a proof. –  Thomash Jun 23 '13 at 11:50
    
It will be long. longer than comment can allow, wait i will update my answer ! –  Shashank Jain Jun 23 '13 at 12:54
2  
@Thomash user2515024 is temporarily suspended. See my proof instead. –  johnchen902 Jun 26 '13 at 13:13
    
Beautiful trick! –  TMS Jun 27 '13 at 1:57
    
@Thomash you're finding the subarray maxes.. you don't need a proof. –  Eiyrioü von Kauyf Jun 28 '13 at 18:44

Using Fibonacci heap, you can do it in O(n + (n-k) log k), which is equal to O(n log k) for small k, for k close to n this becomes O(n).

The algorithm: in fact, you need:

  • n inserts to the heap
  • n-k deletions
  • n-k findmax's

How much these operations cost in Fibonacci heaps? Insert and findmax is O(1) amortized, deletion is O(log n) amortized. So, we have

O(n + (n-k) log k + (n-k)) = O(n + (n-k) log k)
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for how big k? for reasonable-sized k. you can create k k-sized buffers and just iterate over the array keeping track of max element pointers in the buffers - needs no data structures and is O(n) k^2 pre-allocation.

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Sorry, this should have been a comment but I am not allowed to comment for now. @leo and @Clay Goddard You can save yourselves from re-computing the maximum by storing both maximum and 2nd maximum of the window in the beginning (2nd maximum will be the maximum only if there are two maximums in the initial window). If the maximum slides out of the window you still have the next best candidate to compare with the new entry. So you get O(n) , otherwise if you allowed the whole re-computation again the worst case order would be O(nk), k is the window size.

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class MaxFinder
{
    // finds the max and its index
    static int[] findMaxByIteration(int arr[], int start, int end)
    {
        int max, max_ndx; 

        max = arr[start];
        max_ndx = start;
        for (int i=start; i<end; i++)
        {
            if (arr[i] > max)
            {
                max = arr[i];
                max_ndx = i;
            }    
        }

        int result[] = {max, max_ndx};

        return result;
    }

    // optimized to skip iteration, when previous windows max element 
    // is present in current window
    static void optimizedPrintKMax(int arr[], int n, int k)
    {
        int i, j, max, max_ndx;

        // for first window - find by iteration.    
        int result[] = findMaxByIteration(arr, 0, k);

        System.out.printf("%d ", result[0]);

        max = result[0];
        max_ndx = result[1];   

         for (j=1; j <= (n-k); j++)
         {
            // if previous max has fallen out of current window, iterate and find
            if (max_ndx < j)  
            {
                result = findMaxByIteration(arr, j, j+k);
                max = result[0];
                max_ndx = result[1];   
            } 
            // optimized path, just compare max with new_elem that has come into the window 
            else 
            {
                int new_elem_ndx = j + (k-1);
                if (arr[new_elem_ndx] > max)
                {
                    max = arr[new_elem_ndx];
                    max_ndx = new_elem_ndx;
                }      
            }

            System.out.printf("%d ", max);
         }   
    }     

    public static void main(String[] args)
    {
        int arr[] = {10, 9, 8, 7, 6, 5, 4, 3, 2, 1};
        //int arr[] = {1,5,2,6,3,1,24,7};
        int n = arr.length;
        int k = 3;
        optimizedPrintKMax(arr, n, k);
    }
}    
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