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I need help to find an algorithm that finds:

  • four elements in array
  • whose sum equal to a given number X
  • in O(n^2*log(n))

prefer in pseudo-code or c,c++

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closed as off-topic by djechlin, Joshua Taylor, Antti Haapala, Jonathan Potter, MysticMagic Aug 12 '13 at 4:43

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17  
Sounds like homework –  Stephen P Aug 25 '10 at 19:32
3  
Sounds like you need a method of finding all permutations of 4 unique indexes. –  Loki Astari Aug 25 '10 at 19:36
1  
Are numbers greater than zero? Are all numbers unique? –  Dummy00001 Aug 25 '10 at 19:38
1  
Any restriction on X or numbers? –  Nikita Rybak Aug 25 '10 at 19:38
1  
Do you mean that you want write a function that takes an array, its length, and a value and return a set of 4 members of the array whose sum is value? Do you want it to return the set of all possible sets of 4 members whose sum is value? What if there is none found? –  nategoose Aug 25 '10 at 19:53

11 Answers 11

Sounds like homework to me. But here's what I'd do.

First sort the numbers (there's your n*log(n)).

Now, create pointers to the list, initialize it with the first 4 numbers. Once you have that, you check the sum of your 4 current numbers with the total. It should be less than or equal to your search sum (if it's not, you can quit early). Now all you need to do is traverse rest of your list alternately replacing your pointers with the current value in the list. This only need to happen once (or really at worst 4 times) so there's your other n, which makes n^2*log(n)

You'll need to keep track of some logic to know if you're over/under your sum and what to do next, but I leave that as your homework assignment.

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5  
traverse rest of your list alternately replacing your pointers with the current value in the list This part sounds extremely vague to me. –  Nikita Rybak Aug 25 '10 at 19:57
    
Can you give details how you traverse the list with four pointers ? Do you let the first pointer first go to the end, then the second one etc. ? –  Andre Holzner Aug 25 '10 at 20:00
    
By the way, this would be O(n) + O(n * log(n)) = O(n * log(n)), not O(n) * O(n * log(n)) –  Andre Holzner Aug 25 '10 at 20:01

I'm not going to answer your question completely, since I think it is homework and also think that this is easily done. But I do think that I know why you are having difficulty with an answer, so I will help you out a little bit.

Firstly, you should look into recursion. That means calling a function from within itself.

Second, you should use a helper function, which is called by the function you want to write. This function should take as arguments: - an array of numbers - the length of the array - the value you want find members that sum up to - the number of members of the array that you want to sum up

This function will be called by your other function and passed a 4 for the last argument. It will then call itself adjusting the arguments as it tries to find results by partial trial and error.

edit 2

Upon further thought I realized that this not O(n^2), as I claimed earlier (I mentally glossed over the the middle steps). It is limited by n^4, but may have a lower limit than that due to ample opportunity to short cut in many cases. I do not believe that this short cutting improves it to the point of n^2, though.

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And how do you prove the complexity of this is as required? –  Maciej Hehl Aug 25 '10 at 20:40
    
Mission accomplished :) –  Maciej Hehl Aug 25 '10 at 21:25
    
So you think it's easily done and then end up realising you don't know how to do it. Nice. -1. –  IVlad Aug 25 '10 at 22:06
    
@IVLad: I could have deleted the answer and avoided a down vote, but instead I left it up with a note pointing out the flaws with it. –  nategoose Aug 26 '10 at 0:35
    
Thanks all, after a couple of hours today i have reached similar answers like you. I don't need all possible 4 numbers, i need only one option. My solution has also O(n^2) place complexity. –  moti Aug 26 '10 at 16:20

You can do it in O(n^2). Works fine with duplicated and negative numbers.

edit as Andre noted in comment, time is with use of hash, which has 'worst case' (although it's less likely than winning in a lottery). But you can also replace hashtable with balanced tree (TreeMap in java) and get guaranteed stable O(n^2 * log(n)) solution.

Hashtable sums will store all possible sums of two different elements. For each sum S it returns pair of indexes i and j such that a[i] + a[j] == S and i != j. But initially it's empty, we'll populate it on the way.

for (int i = 0; i < n; ++i) {
    // 'sums' hastable holds all possible sums a[k] + a[l]
    // where k and l are both less than i

    for (int j = i + 1; j < n; ++j) {
        int current = a[i] + a[j];
        int rest = X - current;
        // Now we need to find if there're different numbers k and l
        // such that a[k] + a[l] == rest and k < i and l < i
        // but we have 'sums' hashtable prepared for that
        if (sums[rest] != null) {
            // found it
        }
    }

    // now let's put in 'sums' hashtable all possible sums
    // a[i] + a[k] where k < i
    for (int k = 0; k < i; ++k) {
        sums[a[i] + a[k]] = pair(i, k);
    }
}

Let's say, X = a[1] + a[3] + a[7] + a[10]. This sum will be found when i = 7, j = 10 and rest = a[1] + a[3] (indexes 1 and 3 will be found from hash)

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1  
If you use a Tree Map instead of a HashTable (which can have O(n) in the worst case), you're guaranteed to have O(log n) for the lookup of the sums. You should also check that you're not using one number more than once. –  Andre Holzner Aug 25 '10 at 20:11
1  
@Andre I don't think we should consider worst case access time for hash, it's extremely unlikely to happen :) But if that's important, then TreeMap is a solution, yes. –  Nikita Rybak Aug 25 '10 at 20:15
1  
@Andre You should also check that you're not using one number more than once It's already done. i and j are always equals and i < j. And hashtable contains sums for all different indexes k and l less than i. –  Nikita Rybak Aug 25 '10 at 20:17
    
you're right, I didn't realize the way you're updating the sums map and that it contains only indices < i. +1 from me. –  Andre Holzner Aug 25 '10 at 20:31
1  
@IVlad Actually, we need only one pair for each particular sum, so in case of all equal numbers hashtable will have only one element. It's still possible that lots of different sums will have same hash, just difficult to emulate. –  Nikita Rybak Aug 25 '10 at 23:18

Abusing the fact that no memory constrain is specified. And using the usual divide and conquer approach.

Number of all permutations for 4 number subsets is C(n,4) and is O(n^4). Number of all permutations for 2 numbers is C(n,2) and is O(n^2). O(n^2) seems to be OK for the task.

  1. Input is: an array A with n elements, X.
  2. Generate all permutations for 2 number subsets (that's O(n^2)) and put their sums into array B with n^2 elements (also remembering the subsets). Let's denote as S[B[i]] the subset (consisting of the two numbers) whose sum is B[i].
  3. Sort the B, O(n^2*log(n^2)).
  4. Walk through the array B (O(n^2)) i = [0,n^2) and quick search O(log(n^2)) = O(log(n)) in it for the value (X - B[i]). There might be several of them (but not more than n^2).

    4.1. Walk through all the elements with value of (X - B[i]), using index k.

    4.2. Skip the elements B[k] where S[B[k]] intersects with S[B[i]]. Intersection of two sets with two numbers can be calculated in O(1).

    4.3 If k is the index a element where B[i] + B[k] == X and S[B[k]] doesn't intersect with S[B[i]], then the sum of the sets S[B[k]] and S[B[i]] are the four sought numbers.

Performance is: O( n^2 + n^2*log(n^2) + n^2*log(n^2) ) = O( n^2 * log(n^2) ) = O( n^2 * log(n) )

On step four, when we iterate over the multiple matching elements of B using nested loop. Yet, total number of iterations of the two nested loops is limited by the |B| which is O(n^2). The quick search is not the usual variation but the one which finds the matching element with the lowest index. (Alternatively one can use the usual bsearch and since we might have landed in the middle, use two adjacent loops, checking elements in both directions.)

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3  
log(n^2) is 2log(n), so you're not exceeding the time complexity. This will, however, not account for duplicate elements. Additional checks will be needed for that but it's possible. For example given the array [1, 2, 3] and the sums [ 1+2, 1+3, 2+3 ], a desired sum of 9 can be found with 4 + 5, but we are counting 3 twice then. –  Anurag Aug 25 '10 at 20:23
1  
@Anurag: OMG. I had to repeat the math. –  Dummy00001 Aug 25 '10 at 20:34
    
Can you detail the 4th step? How exactly do you deal with duplicates and over/undercounting? –  IVlad Aug 25 '10 at 22:27
1  
@IVlad, I have tried. –  Dummy00001 Aug 26 '10 at 10:22

Like a few other posters, it can be done with a hash in O(n^2)

#include <iostream>
#include <algorithm>
#include <vector>
#include <numeric>
#include <math.h>
#include <map>

using namespace std;

struct Entry
{
   int a;
   int b;
};

int main () {

   typedef vector<int> VI;

   VI l(5);
   l[0] = 1;
   l[1] = 2;
   l[2] = -1;
   l[3] = -2;
   l[4] = 5;
   l[5] = 6;

   sort(l.begin(), l.end());

   int sumTo = 0;

   typedef multimap<int, Entry> Table;

   typedef pair<int,Entry> PairEntry;

   Table myTbl;

   // N
   for (int i = 0; i < l.size(); ++i)
   {
      // N
      for (int j = i+1; j < l.size(); ++j)
      {
         // Const
         int val = l[i] + l[j];

         // A is always less than B
         Entry ent = {i, j};

         myTbl.insert(PairEntry(val,ent));
      }
   }

   pair<Table::iterator, Table::iterator> range;

   // Start at beginning of array
   for (Table::iterator ita = myTbl.begin();
        ita != myTbl.end();
        ++ita)
   {
      int lookFor = sumTo - ita->first;
      // Find the complement
      range = myTbl.equal_range(lookFor);

      // Const bound
      for (Table::iterator itb = range.first;
           itb != range.second;
           ++itb)
      {
         if (ita->second.a == itb->second.a || ita->second.b == itb->second.b)
         {
            // No match
         }
         else
         {
            // Match
            cout << l[ita->second.a] << " " << l[itb->second.a] << " "
                 << l[ita->second.b] << " " << l[itb->second.b] << endl;

            return 0;
         }
      }
   }

   return 0;
}
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1  
This meets the requirements, so +1, but it's not O(n^2) as you say. A C++ multimap doesn't give you constant time insertions and lookups, those are logarithmic. –  IVlad Aug 25 '10 at 22:16

1) Create an array of all possible pair sums [O(N^2)]

2) Sort this array in ascending order [O(N^2 * Log N)]

3) Now this problem reduces to finding 2 numbers in a sorted array that sum to a given number X, in linear time. Use 2 pointers: a LOW pointer starting from the lowest value, and a HIGH pointer starting from the highest value. If the sum is too low, advance LOW. If the sum is too high, advance HIGH (backwards). Eventually they will find that pair or cross each other (this can be easily proven). This process takes linear time in the size of the array, i.e. O(N ^ 2)

This gives a total time of O(N^2 * log N) as required.

NOTE : This method can be generalized for solving the case of M numbers in O(M * N^(M/2) * log N) time.

-- EDIT --

Actually my response is very similar to Dummy00001's response, except the final lookup, where I use a faster method (though the overall complexity is the same...)

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+1 nice solution. But one problem here: suppose u r searching for sum=18. And a = {2,3,4,5,7,9,10} now a[0]+a[1]=5 and a[2]+a[5]=13, so a[0]+a[1]+a[2]+a[5]=18. But a[1]+a[2]=7 and a[0]+a[5]=11 hence a[0]+a[1]+a[2]+a[5]=18. so your solution will print these two instead of 1. So how will you tackle the issue. Thanks. –  Trying Jul 31 '13 at 9:38
    
@Trying: The algorithm isn't required to print a specific set of four; any four distinct numbers having the required sum are ok. The problem with my solution is uniqueness. It may include an array number twice. This can be solved by storing the pairs inside the map as well, and then accepting a match between two pairs only if they have no value in common. –  Eyal Schneider Jul 31 '13 at 14:40
    
True. Thanks for your conformation. I was debugging your solution today and found this, hence wanted to conform from the author. Thanks. –  Trying Jul 31 '13 at 18:25

find four elements in array whose sum equal to a given number X
for me following algorithm works:

Dim Amt(1 To 10) As Long
Dim i

For i = 1 To 10
    Amt(i) = Val(List1.List(i))
Next i

Dim Tot As Integer
Dim lenth As Integer
lenth = List1.ListCount

'sum of 4 numbers
For i = 1 To lenth
    For j = 1 To lenth
        For k = 1 To lenth
            For l = 1 To lenth
                If i <> j And i <> k And i <> l And j <> k And j <> l And k <> l Then
                    Debug.Print CBAmt(i) & " , " & CBAmt(j) & " , " & CBAmt(k) & " , " & CBAmt(l)
                    If CBAmt(i) + CBAmt(j) + CBAmt(k) + CBAmt(l) = Val(Text1) Then
                        MsgBox "Found"
                        found = True
                        Exit For
                    End If
                End If
            Next
            If found = True Then Exit For
        Next
        If found = True Then Exit For
    Next
    If found = True Then Exit For
Next
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1  
This is an O(n^4) solution! –  v1v3kn Mar 31 '13 at 8:13

A working Java solution of the algo. provided by Nikita Rybak above..

// find four numbers in an array such that they equals to X
 class Pair{
     int i;
     int j;

     Pair(int x,int y){
         i=x;
         j=y;
     }
 }

 public class FindNumbersEqualsSum {
    public static void main(String[] args) {

         int num[]={1,2,3,4,12,43,32,53,8,-10,4};

         get4Numbers(num, 17);

         get4Numbers(num, 55);
    }

 public static void get4Numbers(int a[],int sum){

    int len=a.length;

    Map<Integer, Pair> sums = new HashMap<Integer, Pair>(); 
    for (int i = 0; i < len; ++i) {
        // 'sums' hastable holds all possible sums a[k] + a[l]
        // where k and l are both less than i

        for (int j = i + 1; j < len; ++j) {
            int current = a[i] + a[j];
            int rest = sum - current;
            // Now we need to find if there're different numbers k and l
            // such that a[k] + a[l] == rest and k < i and l < i
            // but we have 'sums' hashtable prepared for that
            if (sums.containsKey(rest)) {
                // found it
                Pair p = sums.get(rest);
                System.out.println(a[i]+" + "+a[j]+" + "+a[p.i] +" + "+a[p.j]+" = "+sum);

            }
        }

        // now let's put in 'sums' hashtable all possible sums
        // a[i] + a[k] where k < i
        for (int k = 0; k < i; ++k) {
            sums.put(a[i] + a[k],new Pair(i, k));
        }
    }
 }
}

 Result:

  4 + 8 + 3 + 2 = 17
  8 + 4 + 4 + 1 = 17
  43 + 8 + 3 + 1 = 55
  32 + 8 + 12 + 3 = 55
  8 + -10 + 53 + 4 = 55
  -10 + 4 + 8 + 53 = 55
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This doesnt really handle duplicates - –  cyclotrojan Sep 16 '12 at 21:51
    
Shows 53 + 8 + 4 + 3 = 68 and 8 + 4 + 53 + 3 = 68 –  cyclotrojan Sep 16 '12 at 21:52

I have written an O(N^^2) running time function which does not use hashtables but handles negative numbers and duplicate numbers apparently OK. I handle negative numbers in an integer array by adding an large postive number(e.g. 100) to all the integers in the array. Then, I adjust the target by target += (4 * 100). Then when I find a result, I subtract out the 100 from the integers in the result. Here is my code and test cases: Please let me know if this o(N^^2) time complexity.

struct maryclaranicholascameron{
    int sum;
    int component1;
    int component2;
};


void Another2PrintSum(int arr[], int arraysize, int target){
    int i(arraysize -1);
    int j(arraysize -2);
    int temp(target);
    int temp2(0);
    int m(0);
    int n(0);
    int sum(0);
    int original_target(target);

    for (int ctr = 0; ctr < arraysize; ctr++){

        sum += arr[ctr];
    }

         for (int ctrn = 0; ctrn < arraysize; ctrn++){
        arr[ctrn] += 100;
    }


    maryclaranicholascameron* temparray = new maryclaranicholascameron[sum + (arraysize *100)];
    memset(temparray, 0, sizeof(maryclaranicholascameron) * (sum + 400));



    for (m = 0; m < arraysize; m++){
        for (n = m + 1; n < arraysize; n++){
                temparray[arr[m] + arr[n]].sum = arr[m]+ arr[n];
                temparray[arr[m] + arr[n]].component1 = m;
                temparray[arr[m] + arr[n]].component2 = n;
        }
    }

    target += (4 * 100);
    original_target = target;

    bool found(false);
    while (i >= 0 && i < arraysize && found == false){
        target -= (arr[i]);
        while(j >= 0 && j < arraysize && found == false){
            temp2 = target;
            target -= (arr[j]);
            if (i != j && temparray[target].sum == target && 
                temparray[target].sum != 0 &&
                temparray[target].component1 != i &&
                temparray[target].component2 != i &&
                temparray[target].component1 != j &&
                temparray[target].component2 != j){
                printf("found the 4 integers i = %d j = %d m = %d n = %d component1 = %d component = %d i %d j %d\n",
                    arr[i] - 100,
                    arr[j] - 100,
                    arr[temparray[target].component1] - 100,
                    arr[temparray[target].component2] - 100,
                    temparray[target].component1,
                    temparray[target].component2,
                    i,
                    j);
                    found = true;
                    break;
            }
            j -= 1;
            target = temp2;
        }
        i -= 1;
        j = i;
        target = original_target;
    }
    if (found == false){
        printf("cannot found the 4 integers\n");
    }
    delete [] temparray;
}

// test cases

int maryclaranicholas[] = {-14,-14,-14,-14,-12 ,-12, -12 ,-12 ,-11, -9,-8,-7,40};
 Another2PrintSum(maryclaranicholas, 13,-2};

int testarray[] = {1,3,4,5,7,10};
Another2PrintSum(testarray, 6, 20);
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This problem can be reduced to finding all combinations of length 4. For each combination thus obtained, sum the elements and check if it is equal to X.

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This problem can be taken as a variation of pascals identity,

here is the complete code :

please excuse as the code is in java :

public class Combination {
static int count=0;

public static void main(String[] args) {
    int a[] =  {10, 20, 30, 40, 1, 2,4,11,60,15,5,6};
    int setValue = 4;
    getCombination(a, setValue);

}

private static void getCombination(int[] a, int setValue) {
    // TODO Auto-generated method stub

    int size = a.length;
    int data[] = new int[setValue];
    createCombination(a, data, setValue, 0, 0, size);
    System.out.println(" total combinations : "+count);
}

private static void createCombination(int[] a, int[] data, int setValue,
        int i, int index, int size) {

    // TODO Auto-generated method stub
    if (index == setValue) {

        if(data[0]+data[1]+data[3]+data[2]==91)
        {   count ++;
        for (int j = 0; j < setValue; j++)
            System.out.print(data[j] + " ");
        System.out.println();
        }return;
    }
    // System.out.println(". "+i);
    if (i >= size)
        return;
    // to take care of repetation
    if (i < size - 2) {
        while (a[i] == a[i + 1])
            i++;
    }
    data[index] = a[i];
    // System.out.println(data[index]+" "+index+"  .....");
    createCombination(a, data, setValue, i + 1, index + 1, size);

    createCombination(a, data, setValue, i + 1, index, size);

}

}

Sample input :

int a[] =  {10, 20, 30, 40, 1, 2,4,11,60,15,5,6};

Output : :

10 20 1 60 
10 30 40 11 
10 60 15 6 
20 30 40 1 
20 60 5 6 
30 40 15 6 
11 60 15 5 
 total combinations : 7
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