Given an integer x and a sorted array a of N distinct integers, design a linear-time algorithm to determine if there exists two distinct indices i and j such that a[i] + a[j] == x

  • what if it is distinct but not sorted? what if not-distinct and not-sorted?? – Kalpesh Soni Mar 7 at 22:50
  • Apparently, the OP doesn't believe in showing any effort himself. Here's another question of his. Looks like every time the Prof gave a homework, he ended up up SO. – Abhijit Sarkar Jun 1 at 4:47

11 Answers 11

up vote 35 down vote accepted

This is type of Subset sum problem

Here is my solution. I don't know if it was known earlier or not. Imagine 3D plot of function of two variables i and j:

sum(i,j) = a[i]+a[j]

For every i there is such j that a[i]+a[j] is closest to x. All these (i,j) pairs form closest-to-x line. We just need to walk along this line and look for a[i]+a[j] == x:

 int i = 0; 
 int j = lower_bound(a.begin(), a.end(), x)  -  a.begin(); 
 while (j >= 0 && j < a.size()  &&  i < a.size())  {  
    int sum = a[i]+a[j]; 
    if (sum == x)   { 
        cout << "found: " << i << " " << j << endl;  
        return;
    }
    if (sum > x)    j--;
    else            i++;
    if (i > j) break;
 }  
 cout << " not found\n";

Complexity: O(n)

  • 1
    this works too, also more efficient (due to sorted nature of array). – spotter Aug 13 '12 at 4:21
  • Great! But what about negative values? Removing lower_bound call and set int j = a.size() - 1 could be a solution? – fcatho Jul 25 '16 at 11:35
  • @facho - It should work with negative values. Without lower_bound, it will work, but it'll be less efficient. – Leonid Volnitsky Sep 5 '16 at 4:29
  • Given that this is a code-mostly answer, you might want to mention a programming language, even comment your code (what is it(/_everything_) there for/supposed to accomplish?). I think @fcatho's objection quite valid: check lower_bound(a.begin(), a.end(), x-*a). Why not control the loop just while (i < j)? An alternative approach would use lower_bound(a.begin(), a.end(), x/2) and work inside-out - more complicated loop control. (Just scrolled down to other answers - this is Guru Devanla's.) – greybeard Oct 30 '16 at 14:40
  • what is the complexity of lower_bound ? – Kalpesh Soni Mar 7 at 20:37

think in terms of complements.

iterate over the list, figure out for each item what the number needed to get to X for that number is. stick number and complement into hash. while iterating check to see if number or its complement is in hash. if so, found.

edit: and as I have some time, some pseudo'ish code.

boolean find(int[] array, int x) {
    HashSet<Integer> s = new HashSet<Integer>();

    for(int i = 0; i < array.length; i++) {
        if (s.contains(array[i]) || s.contains(x-array[i])) {
            return true;
        }
        s.add(array[i]);
        s.add(x-array[i]);
    }
    return false;
}
  • Creation of hash map in worst case is O(N^2). – Leonid Volnitsky Aug 13 '12 at 5:11
  • Leonid, agreed, but in general for interview Qs they seem to want to assume hash tables are O(1) (though I guess you get extra points for knowing that it can devolve). With that said, once you understand the hash table version, your solution follows naturally (though not necessarily obviously, have to understand the constraints well to pull it off) as an easy optimization due to the sorted nature. – spotter Aug 13 '12 at 16:57
  • it seems map in C++ generally doesn't work as a regular hash table? For regular hash tables, time complexity is O(1) to O(n) while it is O(lgn) for insert and find in C++. "Complexity(for insertion) If a single element is inserted, logarithmic in size in general, but amortized constant if a hint is given and the position given is the optimal." link – zhenjie Sep 5 '13 at 20:43
  • @zhenjie std::map is usually implemented in Red-Black tree. – mingyc Nov 20 '13 at 16:02
  • 2
    Are you sure that s.add(array[i]); is needed? – Bidou May 12 '15 at 18:21
  1. First pass search for the first value that is > ceil(x/2). Lets call this value L.
  2. From index of L, search backwards till you find the other operand that matches the sum.

It is 2*n ~ O(n)

This we can extend to binary search.

  1. Search for an element using binary search such that we find L, such that L is min(elements in a > ceil(x/2)).

  2. Do the same for R, but now with L as the max size of searchable elements in the array.

This approach is 2*log(n).

  • This may be great,but can you give me more details about what R is? – BlackJoker Apr 11 '13 at 5:28
  • For the binary search L - left, R - right; as in the left and right bounds of the subset. – mctylr Jan 27 '15 at 17:26
  • Note that this wouldn't work if we allowed repeated numbers in the array (as it is sometimes seen in interviews). For example a=[13,13,22] and x=26. You'd get value 22 to match the first search (L=2) and never find R – Philippe Girolami Nov 26 '16 at 14:29
  • Why does this work? Why did you pick ceil(x/2)? – Abhijit Sarkar Jun 1 at 4:58

Here's a python version using Dictionary data structure and number complement. This has linear running time(Order of N: O(N)):

def twoSum(N, x):
    dict = {}

    for i in range(len(N)):
        complement = x - N[i]
        if complement in dict:
            return True
        dict[N[i]] = i

    return False

# Test
print twoSum([2, 7, 11, 15], 9) # True
print twoSum([2, 7, 11, 15], 3) # False
  • Are you sure this works? dict should be populated before the for loop – Maria Ines Parnisari Nov 13 '16 at 2:33
  • You use defaultdict from collections rather than populating dict – subba May 10 '17 at 5:46

Iterate over the array and save the qualified numbers and their indices into the map. The time complexity of this algorithm is O(n).

vector<int> twoSum(vector<int> &numbers, int target) {
    map<int, int> summap;
    vector<int> result;
    for (int i = 0; i < numbers.size(); i++) {
        summap[numbers[i]] = i;
    }
    for (int i = 0; i < numbers.size(); i++) {
        int searched = target - numbers[i];
        if (summap.find(searched) != summap.end()) {
            result.push_back(i + 1);
            result.push_back(summap[searched] + 1);
            break;
        }
    }
    return result;
}
  • 1
    does the summap.find() iterate through all the elements in the map, which could make the complexity grow? – Sai Manoj Jun 7 '16 at 21:10
  • summap.find has O(log n) complexity, so the complexity of this algorithm is O(n log n), not O(n). – Periata Breatta Nov 29 '16 at 9:50

I would just add the difference to a HashSet<T> like this:

public static bool Find(int[] array, int toReach)
{
    HashSet<int> hashSet = new HashSet<int>();

    foreach (int current in array)
    {
        if (hashSet.Contains(current))
        {
            return true;
        }
        hashSet.Add(toReach - current);
    }
    return false;
}

Note: The code is mine but the test file was not. Also, this idea for the hash function comes from various readings on the net.

An implementation in Scala. It uses a hashMap and a custom (yet simple) mapping for the values. I agree that it does not makes use of the sorted nature of the initial array.

The hash function

I fix the bucket size by dividing each value by 10000. That number could vary, depending on the size you want for the buckets, which can be made optimal depending on the input range.

So for example, key 1 is responsible for all the integers from 1 to 9.

Impact on search scope

What that means, is that for a current value n, for which you're looking to find a complement c such as n + c = x (x being the element you're trying ton find a 2-SUM of), there is only 3 possibles buckets in which the complement can be:

  • -key
  • -key + 1
  • -key - 1

Let's say that your numbers are in a file of the following form:

0
1
10
10
-10
10000
-10000
10001
9999
-10001
-9999
10000
5000
5000
-5000
-1
1000
2000
-1000
-2000

Here's the implementation in Scala

import scala.collection.mutable                                                                                                                                                                       
import scala.io.Source

object TwoSumRed {
  val usage = """ 
    Usage: scala TwoSumRed.scala [filename]
  """

  def main(args: Array[String]) {
    val carte = createMap(args) match {
      case None => return
      case Some(m) => m
    }

    var t: Int = 1

    carte.foreach {
      case (bucket, values) => {
        var toCheck: Array[Long] = Array[Long]() 

        if (carte.contains(-bucket)) {
          toCheck = toCheck ++: carte(-bucket)
        }
        if (carte.contains(-bucket - 1)) {
          toCheck = toCheck ++: carte(-bucket - 1)
        }
        if (carte.contains(-bucket + 1)) {
          toCheck = toCheck ++: carte(-bucket + 1)
        }

        values.foreach { v =>
          toCheck.foreach { c =>
            if ((c + v) == t) {
              println(s"$c and $v forms a 2-sum for $t")
              return
            }
          }
        }
      }
    }
  }

  def createMap(args: Array[String]): Option[mutable.HashMap[Int, Array[Long]]] = {
    var carte: mutable.HashMap[Int,Array[Long]] = mutable.HashMap[Int,Array[Long]]()

    if (args.length == 1) {
      val filename = args.toList(0)
      val lines: List[Long] = Source.fromFile(filename).getLines().map(_.toLong).toList
      lines.foreach { l =>
        val idx: Int = math.floor(l / 10000).toInt
        if (carte.contains(idx)) {
          carte(idx) = carte(idx) :+ l
        } else {
          carte += (idx -> Array[Long](l))
        }
      }
      Some(carte)
    } else {
      println(usage)
      None
    }
  }
}
int[] b = new int[N];
for (int i = 0; i < N; i++)
{
    b[i] = x - a[N -1 - i];
}
for (int i = 0, j = 0; i < N && j < N;)
    if(a[i] == b[j])
    {
       cout << "found";
       return;
     } else if(a[i] < b[j])
        i++;
     else
        j++;
cout << "not found";
  • ,You came up with a really nice algorithm. How about the case where a[i] == b[j] and index i equals index j? Thanks. – Frank Apr 25 at 0:17

Here is a linear time complexity solution O(n) time O(1) space

 public void twoSum(int[] arr){

   if(arr.length < 2) return;

   int max = arr[0] + arr[1];
   int bigger = Math.max(arr[0], arr[1]);
   int smaller = Math.min(arr[0], arr[1]);
   int biggerIndex = 0;
   int smallerIndex = 0;

    for(int i = 2 ; i < arr.length ; i++){

        if(arr[i] + bigger <= max){ continue;}
        else{
            if(arr[i] > bigger){
                smaller = bigger;
                bigger = arr[i];
                biggerIndex = i;
            }else if(arr[i] > smaller)
            {
                smaller = arr[i];
                smallerIndex = i;
            }
            max = bigger + smaller;
        }

    }

    System.out.println("Biggest sum is: " + max + "with indices ["+biggerIndex+","+smallerIndex+"]");

}

Solution

  • We need array to store the indices
  • Check if the array is empty or contains less than 2 elements
  • Define the start and the end point of the array
  • Iterate till condition is met
  • Check if the sum is equal to the target. If yes get the indices.
  • If condition is not met then traverse left or right based on the sum value
  • Traverse to the right
  • Traverse to the left

For more info :[http://www.prathapkudupublog.com/2017/05/two-sum-ii-input-array-is-sorted.html enter image description here

Credit to leonid

His solution in java, if you want to give it a shot

I removed the return, so if the array is sorted, but DOES allow duplicates, it still gives pairs

static boolean cpp(int[] a, int x) {
    int i = 0;
    int j = a.length - 1;
    while (j >= 0 && j < a.length && i < a.length) {
        int sum = a[i] + a[j];
        if (sum == x) {
        System.out.printf("found %s, %s \n", i, j);
//                return true;
        }
        if (sum > x) j--;
        else i++;
        if (i > j) break;
    }
    System.out.println("not found");
    return false;
    }

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