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We need to find pair of numbers in an array whose sum is equal to a given value.

A = {6,4,5,7,9,1,2}

Sum = 10 Then the pairs are - {6,4} , {9,1}

I have two solutions for this .

  • an O(nlogn) solution - sort + check sum with 2 iterators (beginning and end).
  • an O(n) solutiin - hashing the array. Then checking if sum-hash[i] exists in the hashtable or not.

But , the problem is that although the second solution is O(n) time , but uses O(n) space as well.

So , I was wondering if we could do it in O(n) time and O(1) space. And this is NOT homework!

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1  
numbers need to be consecutive??? – Shashank Kadne Mar 11 '12 at 16:42
1  
I doubt such algorithm exist... – Petar Minchev Mar 11 '12 at 16:43
1  
By saying consecutive here, I mean do they need to follow each other in the given sequence???....In your examples..[6,4] and [9,1] were in a sequence.....4 was neighbor of 6 and 1 was neighbor of 9.... – Shashank Kadne Mar 11 '12 at 16:52
2  
@TedHopp: The problem you describe can be easily solved if you create the hashset and check if an element exist in the same iteration. [and not first creating a full hash-set, and only later checking for a pair] – amit Mar 11 '12 at 16:56
2  
I dont think it can be done with O(1) space constraint. – shiplu.mokadd.im Mar 11 '12 at 17:01

14 Answers 14

Use in-place radix sort and OP's first solution with 2 iterators, coming towards each other.

If numbers in the array are not some sort of multi-precision numbers and are, for example, 32-bit integers, you can sort them in 2*32 passes using practically no additional space (1 bit per pass). Or 2*8 passes and 16 integer counters (4 bits per pass).


Details for the 2 iterators solution:

First iterator initially points to first element of the sorted array and advances forward. Second iterator initially points to last element of the array and advances backward.

If sum of elements, referenced by iterators, is less than the required value, advance first iterator. If it is greater than the required value, advance second iterator. If it is equal to the required value, success.

Only one pass is needed, so time complexity is O(n). Space complexity is O(1). If radix sort is used, complexities of the whole algorithm are the same.


If you are interested in related problems (with sum of more than 2 numbers), see "Sum-subset with a fixed subset size" and "Finding three elements in an array whose sum is closest to an given number".

share|improve this answer
    
I have trouble saying that radix sort actually takes time O(N), since it depends on the size of the machine word. For a fixed machine it's O(N), but more generally this is O(N log U), where U is the maximum possible integer representable. – templatetypedef Mar 11 '12 at 20:04
    
@EvgenyKluev : Seems quite close to what is required. But then radix sort is O(kn) which is not any better than O(nlogn). Could you explain how you are calling it O(n) ? – h4ck3d Mar 11 '12 at 22:11
    
@EvgenyKluev : If each key is of 9 digits then complexity of radix would be high – h4ck3d Mar 11 '12 at 22:29
    
@templatetypedef, @NiteeshMehra, yes, in general case radix sort is O(N log U). Also, computing the hash function is O(log U). Filling and using the hashtable is O(N log U). Since OP's second solution assumes complexity O(N), we have O(N log U) = O(N). Or O(U) = 1. Which allows me to assume O(N) for radix sort. Isn't it reasonable? Anyway, if O(U) > 1, we cannot have O(N) solution at all because we have to process N log U bits (worst case) or N log N bits (on average, for uniformly distributed numbers and N < U). – Evgeny Kluev Mar 12 '12 at 4:33
    
@NiteeshMehra, If each key is of 9 decimal digits, it contains about 32 bits. You can sort it in 16 passes (as explained in my answer), or you can do it in 8 passes with 8 bits per pass and 256 counters. In practice, it may be better than O(N log N) of comparison sort - if N is large, or it may be worse if N is small. – Evgeny Kluev Mar 12 '12 at 4:42
for (int i=0; i < array.size(); i++){
  int value = array[i];
  int diff = sum - value; 
  if (! hashSet.contains(diffvalue)){
      hashSet.put(value,value);
  } else{
       printf(sum = diffvalue + hashSet.get(diffvalue));
  } 
}

--------
Sum being sum of 2 numbers.
share|improve this answer
    
Whats the difference between hashing and your solution ? – h4ck3d Dec 1 '12 at 9:29
    
Nothing his is still O(N) space – sreya Sep 23 '13 at 21:31
4  
OP explicitly said no extra space.. why is this answer upvoted? – KodeSeeker Nov 16 '13 at 0:57
    
try it with array=[ 1, 2, 10, 3, 4], and sum = 20 – chouaib May 29 '15 at 4:48

This is a classic interview question from Microsoft research Asia.
How to Find 2 numbers in an unsorted array equal to a given sum.

[1]brute force solution
This algorithm is very simple. The time complexity is O(N^2)

[2]Using binary search
Using bianry searching to find the Sum-arr[i] with every arr[i], The time complexity can be reduced to O(N*logN)

[3]Using Hash
Base on [2] algorithm and use hash, the time complexity can be reduced to O(N), but this solution will add the O(N) space of hash.

[4]Optimal algorithm:

Pseduo-code:

for(i=0;j=n-1;i<j)
   if(arr[i]+arr[j]==sum) return (i,j);
else if(arr[i]+arr[j]<sum) i++;
else j--;
return(-1,-1);

or

If a[M] + a[m] > I then M--
If a[M] + a[m] < I then m++
If a[M] + a[m] == I you have found it
If m > M, no such numbers exist.

And, Is this quesiton completely solved? No. If the number is N. This problem will become very complex.

The quesiton then:
How can I find all the combination cases with a given number?

This is a classic NP-Complete problem which is called subset-sum.
To understand NP/NPC/NP-Hard you'd better to read some professional books.

References:
[1]http://www.quora.com/Mathematics/How-can-I-find-all-the-combination-cases-with-a-given-number
[2]http://en.wikipedia.org/wiki/Subset_sum_problem

share|improve this answer
    
Your second solution is not correct. How can we do binary search in unsorted array? – Hengameh May 5 '15 at 10:56
1  
also the forth one! it is not correct! your array is not sorted, you cannot increment or decrement indexes. you may miss some of them. – Hengameh May 5 '15 at 10:58

If you assume that the value M to which the pairs are suppose to sum is constant and that the entries in the array are positive, then you can do this in one pass (O(n) time) using M/2 pointers (O(1) space) as follows. The pointers are labeled P1,P2,...,Pk where k=floor(M/2). Then do something like this

for (int i=0; i<N; ++i) {
  int j = array[i];
  if (j < M/2) {
    if (Pj == 0)
      Pj = -(i+1);   // found smaller unpaired
    else if (Pj > 0)
      print(Pj-1,i); // found a pair
      Pj = 0;
  } else
    if (Pj == 0)
      Pj = (i+1);    // found larger unpaired
    else if (Pj < 0)
      print(Pj-1,i); // found a pair
      Pj = 0;
  }
}

You can handle repeated entries (e.g. two 6's) by storing the indices as digits in base N, for example. For M/2, you can add the conditional

  if (j == M/2) {
    if (Pj == 0)
      Pj = i+1;      // found unpaired middle
    else
      print(Pj-1,i); // found a pair
      Pj = 0;
  } 

But now you have the problem of putting the pairs together.

share|improve this answer
1  
Shouldn't Pj be more like P[j]? – svick Mar 11 '12 at 17:26
    
With these assumptions, can't we just create an array which will be histogram/set of size M? – amit Mar 11 '12 at 17:32
3  
if M is constant, I have a simpler algorithm. Make M/2 passes on the array, looking for 1 and M-1 on the 1st pass, 2 and M-2 on the 2nd pass and so on, in O(NM) = O(N) time. – Ali Ferhat Mar 11 '12 at 17:33
4  
Saying that M is O(1) seems like cheating. If M is O(1) then there will be only O(1) unique values in the array that can participate in the sum, so you'd just need O(n) time to find those values and then any algorithm you use will be O(1) time and space. – interjay Mar 11 '12 at 17:39
    public void printPairsOfNumbers(int[] a, int sum){
    //O(n2)
    for (int i = 0; i < a.length; i++) {
        for (int j = i+1; j < a.length; j++) {
            if(sum - a[i] == a[j]){
                //match..
                System.out.println(a[i]+","+a[j]);
            }
        }
    }

    //O(n) time and O(n) space
    Set<Integer> cache = new HashSet<Integer>();
    cache.add(a[0]);
    for (int i = 1; i < a.length; i++) {
        if(cache.contains(sum - a[i])){
            //match//
            System.out.println(a[i]+","+(sum-a[i]));
        }else{
            cache.add(a[i]);
        }
    }

}
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Does the obvious solution not work (iterating over every consecutive pair) or are the two numbers in any order?

In that case, you could sort the list of numbers and use random sampling to partition the sorted list until you have a sublist that is small enough to be iterated over.

share|improve this answer
    
sorting is O(nlogn), iterating over consecutive pairs fails, for example: {9,3,1} sum is 10. – amit Mar 11 '12 at 16:49
1  
@Blender iterating over pairs = O(n^2) – h4ck3d Mar 11 '12 at 16:50
1  
@amit: sorting could be O(n) depending on the constraints on the input numbers – BrokenGlass Mar 11 '12 at 16:50
    
I'm not sure if there exists a O(n) solution that takes up O(1) space for something this complicated. – Blender Mar 11 '12 at 16:51
2  
@amit what is best sorting algorithm with O(n*sqrt(loglogn)) for unbounded range? – Saeed Amiri Mar 11 '12 at 18:19
public static ArrayList<Integer> find(int[] A , int target){
    HashSet<Integer> set = new HashSet<Integer>();
    ArrayList<Integer> list = new ArrayList<Integer>();
    int diffrence = 0;
    for(Integer i : A){
        set.add(i);
    }
    for(int i = 0; i <A.length; i++){
        diffrence = target- A[i];
    if(set.contains(diffrence)&&A[i]!=diffrence){
        list.add(A[i]);
        list.add(diffrence);
        return list;
    }
     }
    return null;
}
share|improve this answer
`package algorithmsDesignAnalysis;

 public class USELESStemp {
 public static void main(String[] args){
    int A[] = {6, 8, 7, 5, 3, 11, 10}; 

    int sum = 12;
    int[] B = new int[A.length];
    int Max =A.length; 

    for(int i=0; i<A.length; i++){
        B[i] = sum - A[i];
        if(B[i] > Max)
            Max = B[i];
        if(A[i] > Max)
            Max = A[i];

        System.out.print(" " + B[i] + "");

    } // O(n) here; 

    System.out.println("\n Max = " + Max);

    int[] Array = new int[Max+1];
    for(int i=0; i<B.length; i++){
        Array[B[i]] = B[i];
    } // O(n) here;

    for(int i=0; i<A.length; i++){  
    if (Array[A[i]] >= 0)
        System.out.println("We got one: " + A[i] +" and " + (sum-A[i]));
    } // O(n) here;

} // end main();

/******
Running time: 3*O(n)
*******/
}
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Below code takes the array and the number N as the target sum. First the array is sorted, then a new array containing the remaining elements are taken and then scanned not by binary search but simple scanning of the remainder and the array simultaneously.

public static int solution(int[] a, int N) {

    quickSort(a, 0, a.length-1);    // nlog(n)

    int[] remainders = new int[a.length];

    for (int i=0; i<a.length; i++) {
        remainders[a.length-1-i] = N - a[i];     // n
    }

    int previous = 0;

    for (int j=0; j<a.length; j++) {            // ~~ n

        int k = previous;

        while(k < remainders.length && remainders[k] < a[j]) {
            k++;
        }

        if(k < remainders.length && remainders[k] == a[j]) {
            return 1;
        }

        previous = k;
    }

    return 0;
}
share|improve this answer

Shouldn't iterating from both ends just solve the problem?

Sort the array. And start comparing from both ends.

if((arr[start] + arr[end]) < sum) start++;
if((arr[start] + arr[end]) > sum) end--;
if((arr[start] + arr[end]) = sum) {print arr[start] "," arr[end] ; start++}
if(start > end)  break;

Time Complexity O(nlogn)

share|improve this answer

if its a sorted array and we need only pair of numbers and not all the pairs we can do it like this:

public void sums(int a[] , int x){ // A = 1,2,3,9,11,20 x=11
    int i=0 , j=a.length-1;
    while(i < j){
      if(a[i] + a[j] == x) system.out.println("the numbers : "a[x] + " " + a[y]);
      else if(a[i] + a[j] < x) i++;
      else j--;
    }
}

1 2 3 9 11 20 || i=0 , j=5 sum=21 x=11
1 2 3 9 11 20 || i=0 , j=4 sum=13 x=11
1 2 3 9 11 20 || i=0 , j=4 sum=11 x=11
END

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The following code returns true if two integers in an array match a compared integer.

 function compareArraySums(array, compare){

        var candidates = [];

        function compareAdditions(element, index, array){
            if(element <= y){
                candidates.push(element);
            }
        }

        array.forEach(compareAdditions);

        for(var i = 0; i < candidates.length; i++){
            for(var j = 0; j < candidates.length; j++){
                if (i + j === y){
                    return true;
                }
            }
        }
    }
share|improve this answer

Python 2.7 Implementation:

import itertools
list = [1, 1, 2, 3, 4, 5,]
uniquelist = set(list)
targetsum = 5
for n in itertools.combinations(uniquelist, 2):
    if n[0] + n[1] == targetsum:
    print str(n[0]) + " + " + str(n[1])

Output:

1 + 4
2 + 3
share|improve this answer
1  
I can see the notational ease. Care to argue space and time complexity? The questions about ends with O(n) time and O(1) space? – greybeard Dec 7 '15 at 7:39

https://github.com/clockzhong/findSumPairNumber

#! /usr/bin/env python
import sys
import os
import re


#get the number list
numberListStr=raw_input("Please input your number list (seperated by spaces)...\n")
numberList=[int(i) for i in numberListStr.split()]
print 'you have input the following number list:'
print numberList

#get the sum target value
sumTargetStr=raw_input("Please input your target number:\n")
sumTarget=int(sumTargetStr)
print 'your target is: '
print sumTarget


def generatePairsWith2IndexLists(list1, list2):
    result=[]
    for item1 in list1:
        for item2 in list2:
            #result.append([item1, item2])
            result.append([item1+1, item2+1])
    #print result
    return result

def generatePairsWithOneIndexLists(list1):
    result=[]
    index = 0
    while index< (len(list1)-1):
        index2=index+1
        while index2 < len(list1):
            #result.append([list1[index],list1[index2]])
            result.append([list1[index]+1,list1[index2]+1])
            index2+=1
        index+=1
    return result


def getPairs(numList, target):
    pairList=[]
    candidateSlots=[] ##we have (target-1) slots 

    #init the candidateSlots list
    index=0
    while index < target+1:
        candidateSlots.append(None)
        index+=1

    #generate the candidateSlots, contribute O(n) complexity
    index=0
    while index<len(numList):
        if numList[index]<=target and numList[index]>=0:
            #print 'index:',index
            #print 'numList[index]:',numList[index]     
            #print 'len(candidateSlots):',len(candidateSlots)
            if candidateSlots[numList[index]]==None:
                candidateSlots[numList[index]]=[index]
            else:
                candidateSlots[numList[index]].append(index)
        index+=1

    #print candidateSlots

    #generate the pairs list based on the candidateSlots[] we just created
    #contribute O(target) complexity
    index=0
    while index<=(target/2):
        if candidateSlots[index]!=None and candidateSlots[target-index]!=None:
            if index!=(target-index):
                newPairList=generatePairsWith2IndexLists(candidateSlots[index], candidateSlots[target-index])
            else:
                newPairList=generatePairsWithOneIndexLists(candidateSlots[index])
            pairList+=newPairList
        index+=1

    return pairList

print getPairs(numberList, sumTarget)

I've successfully implemented one solution with Python under O(n+m) time and space cost. The "m" means the target value which those two numbers' sum need equal to. I believe this is the lowest cost could get. Erict2k used itertools.combinations, it'll also cost similar or higher time&space cost comparing my algorithm.

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