# Given an array of numbers, find out if 3 of them add up to 0

Given an array of numbers, find out if 3 of them add up to 0.

Do it in N^2, how would one do this?

-
Just as a pointer, the general form of this problem is called "subset sum" if you want to look up more info about it. The general form is NP-complete, but it's tractable if you restrict the subsets you're looking at to some fixed size (in this case 3). –  Tyler McHenry Aug 16 '09 at 1:00
Does the array contain negative numbers, or only positive numbers? Does it contain zeros? –  Alex Aug 16 '09 at 19:17

O(n^2) solution without hash tables (because using hash tables is cheating :P). Here's the pseudocode:

``````Sort the array // O(nlogn)

for each i from 1 to len(array) - 1
iter = i + 1
reviter = len(array) - 1
while iter < reviter
tmp = array[iter] + array[reviter] + array[i]
if  tmp > 0
reviter--
else if tmp < 0
iter++
else
return true
return false
``````

Basically using a sorted array, for each number (target) in an array, you use two pointers, one starting from the front and one starting from the back of the array, check if the sum of the elements pointed to by the pointers is >, < or == to the target, and advance the pointers accordingly or return true if the target is found.

-
This is way better than the hash table solution –  leiz Aug 16 '09 at 3:56
Agreed. This general technique is a good one to know for solving similar problems. –  caf Aug 16 '09 at 4:50
What is len(n)? Is that the index of target? –  hughdbrown Aug 16 '09 at 15:09
len(n) is the length of the array :) –  Charles Ma Aug 16 '09 at 23:08
hey charles, i have 1 more question. In your code, isn't it possible for the target to be the same as the array[inter] or array[reviter]? So then you are adding the same number twice? –  ryan Aug 16 '09 at 23:17

put the negative of each number into a hash table or some other constant time lookup data structure. (n)

loop through the array getting each set of two numbers (n^2), and see if their sum is in the hash table.

-
This solution will also work for a slightly different question: Are there three/four numbers which sum can be devided by a constant q without remainder? –  Anna Aug 16 '09 at 5:35
This works but it uses O(n) memory which can be avoided if we use one of the other solutions mentioned above. –  tdeegan Nov 20 at 16:29

Not for credit or anything, but here is my python version of Charles Ma's solution. Very cool.

``````def find_sum_to_zero(arr):
arr = sorted(arr)
for i, target in enumerate(arr):
lower, upper = 0, len(arr)-1
while lower < i < upper:
tmp = target + arr[lower] + arr[upper]
if tmp > 0:
upper -= 1
elif tmp < 0:
lower += 1
else:
yield arr[lower], target, arr[upper]
lower += 1
upper -= 1

if __name__ == '__main__':
# Get a list of random integers with no duplicates
from random import randint
arr = list(set(randint(-200, 200) for _ in range(50)))
for s in find_sum_to_zero(arr):
print s
``````

Much later:

``````def find_sum_to_zero(arr):
limits = 0, len(arr)-1
for i, target in enumerate(sorted(arr)):
lower, upper = limits
while lower < i < upper:
values = (arr[lower], target, arr[upper])
tmp = sum(values)
if not tmp:
yield values
lower += tmp <= 0
upper -= tmp >= 0
``````
-
I love how python looks just like pseudocode! –  Charles Ma Aug 16 '09 at 23:10
maybe it does to python coders, not to me. :p –  Jason S Aug 17 '09 at 13:23
If you want an explanation, here are the non-obvious bits for a non-python developer: (1) enumerate returns each element of a sequence with its integer index, starting from 0 (2) "lower < i < upper" means "lower < i and i < upper" in a single test (3) yield returns a value from a function but allows execution to continue from that point the next time it is requested (4) set() returns a group of unique items, dumping multiple occurrences (5) multiple variables can be assigned in a single statement (6) the generator statement says, "Give me 50 integers in the range -200 to 200 –  hughdbrown Aug 17 '09 at 13:43

This is a well known problem in CS: http://en.wikipedia.org/wiki/3SUM

-

Not trying to boast about my programming skills or add redundant stuff here. Just wanted to provide beginners with an implementation in C++. Implementation based on the pseudocode provided by Charles Ma. I hope the comments help.

``````#include <iostream>
using namespace std;

void merge(int originalArray[], int low, int high, int sizeOfOriginalArray){
//    Step 4: Merge sorted halves into an auxiliary array
int aux[sizeOfOriginalArray];
int auxArrayIndex, left, right, mid;

auxArrayIndex = low;
mid = (low + high)/2;
right = mid + 1;
left = low;

//    choose the smaller of the two values "pointed to" by left, right
//    copy that value into auxArray[auxArrayIndex]
//    increment either left or right as appropriate
//    increment auxArrayIndex
while ((left <= mid) && (right <= high)) {
if (originalArray[left] <= originalArray[right]) {
aux[auxArrayIndex] = originalArray[left];
left++;
auxArrayIndex++;
}else{
aux[auxArrayIndex] = originalArray[right];
right++;
auxArrayIndex++;
}
}

//    here when one of the two sorted halves has "run out" of values, but
//    there are still some in the other half; copy all the remaining values
//    to auxArray
//    Note: only 1 of the next 2 loops will actually execute
while (left <= mid) {
aux[auxArrayIndex] = originalArray[left];
left++;
auxArrayIndex++;
}

while (right <= high) {
aux[auxArrayIndex] = originalArray[right];
right++;
auxArrayIndex++;
}

//    all values are in auxArray; copy them back into originalArray
int index = low;
while (index <= high) {
originalArray[index] = aux[index];
index++;
}
}

void mergeSortArray(int originalArray[], int low, int high){
int sizeOfOriginalArray = high + 1;
//    base case
if (low >= high) {
return;
}

//    Step 1: Find the middle of the array (conceptually, divide it in half)
int mid = (low + high)/2;

//    Steps 2 and 3: Recursively sort the 2 halves of origianlArray and then merge those
mergeSortArray(originalArray, low, mid);
mergeSortArray(originalArray, mid + 1, high);
merge(originalArray, low, high, sizeOfOriginalArray);
}

//O(n^2) solution without hash tables
//Basically using a sorted array, for each number in an array, you use two pointers, one starting from the number and one starting from the end of the array, check if the sum of the three elements pointed to by the pointers (and the current number) is >, < or == to the targetSum, and advance the pointers accordingly or return true if the targetSum is found.

bool is3SumPossible(int originalArray[], int targetSum, int sizeOfOriginalArray){
int high = sizeOfOriginalArray - 1;
mergeSortArray(originalArray, 0, high);

int temp;

for (int k = 0; k < sizeOfOriginalArray; k++) {
for (int i = k, j = sizeOfOriginalArray-1; i <= j; ) {
temp = originalArray[k] + originalArray[i] + originalArray[j];
if (temp == targetSum) {
return true;
}else if (temp < targetSum){
i++;
}else if (temp > targetSum){
j--;
}
}
}
return false;
}

int main()
{
int arr[] = {2, -5, 10, 9, 8, 7, 3};
int size = sizeof(arr)/sizeof(int);
int targetSum = 5;

//3Sum possible?
bool ans = is3SumPossible(arr, targetSum, size); //size of the array passed as a function parameter because the array itself is passed as a pointer. Hence, it is cummbersome to calculate the size of the array inside is3SumPossible()

if (ans) {
cout<<"Possible";
}else{
cout<<"Not possible";
}

return 0;
}
``````
-