# Finding two non-subsequent elements in array which sum is minimal

Intro: As far as I could search, this question wasn't asked in SO yet.
This is an interview question.
I am not even specifically looking for a code solution, any algorithm/pseudocode will work.

The problem: Given an integer array `int[] A` and its size `N`, find 2 non-subsequent (can't be adjacent in the array) elements with minimal sum. Also the answer must not contain the first or last elements (index `0` and `n-1`). Also the solution should be in `O(n)` time and space complexity.

E.g. when `A = [5, 2, 4, 6, 3, 7]` the answer is `5`, since `2+3=5`.
When `A = [1, 2, 3, 3, 2, 1]` the answer is `4`, since `2+2=4` and you can't choose either of the `1`'s since the are at the ends of the array.

Attempt: At first I thought that one of the numbers in the solution must be the smallest one in the array (besides the first and last), but this was refuted quickly with the counter-example
`A = [4, 2, 1, 2, 4]` `-> 4 (2+2)`

Then I thought that if I find the 2 smallest numbers (besides the first and last) in the array, the solution will be those two. This obviously quickly failed because I can't choose 2 adjacent numbers, and if I have to choose non-adjacent numbers then this is the very definition of the question :).

Finally I thought, well, I will just find the 3 smallest numbers (besides the first and last) in the array, and the solution will have to be two of those, since two of those have to not be adjacent to each other. This also failed due to `A = [2, 2, 1, 2, 4, 2, 6]` `-> 2+1=3` , which seems to work because I will find `2, 1, 2`, but assuming I am finding the `2, 1, 2` in indexes `1, 2, 3` this won't necessarily work (it would if I found specifically the `2` in index `5` but I can't guarantee that unfortunately).

Question: Now I'm stumped, can anyone come up with a solution/idea that works?

-
Are you sure it can be solved in O(n) time? – Matthew D Feb 4 at 19:13
@MatthewD that's what the guy said :) – Idos Feb 4 at 19:17
How about modifying the three smallest numbers approach to include the indexes as well. You would need 6 places to store - 3 indexes, 3 values. If you see a duplicate value then just update the index so that in your example upon seeing the '2' at index '5' the the 2nd index can be updated as 5 thus making elements at '2' and '5' as the solutions in the same pass. Just be sure to update index for duplicates only if the one's that are being tracked are already adjacent. – Ravindra HV Feb 4 at 19:35
You probably could use a variation of the Kadane's algorithm to solve this. – higuaro Feb 5 at 7:31
@higuaro, I think it would need a lot of variation, as that algorithm relies heavily on selected elements being adjacent, where here the requirement is opposite. – trincot Feb 5 at 15:10

Here is a live javascript implementation of an algorithm that:

• finds the 4 smallest elements (excluding first/last element from search)
• finds the pairs of these 4 elements that are not adjacent in original array
• finds from these pairs the one with the minimal sum

``````function findMinNonAdjacentPair(a) {
var mins = [];

// quick exits:
if (a.length < 5) return {error: "no solution, too few elements."};
if (a.some(isNaN)) return {error: "non-numeric values given."};

// collect 4 smallest values by their indexes
for (var i = 1; i < a.length - 1; i++) { // O(n)
if (mins.length < 4 || a[i] < a[mins[3]]) {
// need to keep record of this element in sorted list of 4 elements
for (var j = Math.min(mins.length - 1, 2); j >= 0; j--) { // O(1)
if (a[i] >= a[mins[j]]) break;
mins[j+1] = mins[j];
}
mins[j+1] = i;
}
}
// mins now has the indexes to the 4 smallest values

// Find the smallest sum
var result = {
sum: a[mins[mins.length-1]]*2+1 // large enough
}

for (var j = 0; j < mins.length-1; j++) { // O(1)
for (var k = j + 1; k < mins.length; k++) {
if (Math.abs(mins[j] - mins[k]) > 1) { // not adjacent
if (result.sum    > a[mins[j]]+a[mins[k]]) {
result.sum    = a[mins[j]]+a[mins[k]];
result.index1 = mins[j];
result.index2 = mins[k];
};
if (k < j + 3) return result; // cannot be improved
break; // exit inner loop: it cannot bring improvement
}
}
}
return result;
}

// Get I/O elements
var input = document.getElementById('in');
var output = document.getElementById('out');
var select = document.getElementById('pre');

function process() {
// translate input to array of numbers
var a = input.value.split(',').map(Number);
// call main function and display returned value
}

// respond to selection from list
select.onchange = function() {
input.value = select.value;
process();
}

// respond to change in input box
input.oninput = process;

// and produce result upon load:
process();``````
``````Type comma-separated list of values (or select one):</br>
<input id="in" value="2, 2, 1, 2, 4, 2, 6"> &lt;=
<select id="pre">
<option value="5, 2, 4, 6, 3, 7">5, 2, 4, 6, 3, 7</option>
<option value="1, 2, 3, 3, 2, 1">1, 2, 3, 3, 2, 1</option>
<option value="4, 2, 1, 2, 4">4, 2, 1, 2, 4</option>
<option value="2, 2, 1, 2, 4, 2, 6" selected>2, 2, 1, 2, 4, 2, 6</option>
</select>
</br>
Output:</br>
<pre id="out"></pre>``````

The algorithm has a few loops with following big-O complexities:

• find 4 smallest values: O(n), as the inner loop runs at most 3 times, which is O(1)
• find the smallest sum of non-adjacent pairs has a double loop: in total the body will run at most 4 times = O(1). NB: The number of possible pairs is 6, but the execution is guaranteed to break out of the loops sooner.

So the algorithm runs in O(n).

-
1. Find the smallest number beside the first and the last.
2. Find the second smallest that is not a neighbour of the first one and not the first or last one in the array. Then build the sum.

• If the first element is the second or the penultimate element you already have the solution.
3. Otherwise calculate the sum of both neighbours of the first number. check if its smaller then the first sum

• if not: take the first sum
• otherwise take the second one

This will always work because if the first sum is not the answer that means the first number cannot be part of the solution. And that on the other hand means, the solution can just be the second sum.

-
This is missing a crucial element of excluding the ends from steps 2 and 3. However if you just remove both ends as step 0 (and consider all elements in step 1), then all should work OK. – Michael Anderson Feb 5 at 0:24
I added you suggestion to the answer – RomCoo Feb 8 at 0:11

Find the four smallest and consider all possibilities among those four. The smallest is nonadjacent to at least one of the second, third, or fourth smallest; the only other possibility that could be better is the second and third smallest (assuming that they are nonadjacent).

-
I am writing some code to test this. If it is right then kudos! :) – Idos Feb 4 at 19:40
We would either need track the indexes to avoid another pass is it not ? – Ravindra HV Feb 4 at 19:47
@RavindraHV Yes, that was implicit in the asker's attempted solutions as well. – David Eisenstat Feb 4 at 19:49
If you call these numbers 1, 2, 3, 4 then the smallest sum is 1+2 if non adjacent, otherwise 1+3 if non-adjacent, otherwise 2+3 and 1+4 are both nonadjacent and the optimal result is the smaller sum. – gnasher729 Feb 4 at 23:48

I think this does not need any deep reasoning, and can be solved in a single pass, keeping the optimal solution of the array elements processed so far:

``````public static int[] minimumSumOfNonAcjacentElements(int[] a) {
// the result for the sequence a[1:i]
int minSum = Integer.MAX_VALUE;
int minSumElement1 = Integer.MAX_VALUE;
int minSumElement2 = Integer.MAX_VALUE;

// the minimum element eligible for joining with a[i], i.e. from a[1 : i-2]
int minElement = a[1];

int prevElement = a[2]; // a[i - 1]
for (int i = 3; i + 1 < a.length; i++) {
int sum = minElement + a[i];
if (sum < minSum) {
minSum = sum;
minSumElement1 = minElement;
minSumElement2 = a[i];
}

if (prevElement < minElement) {
minElement = prevElement;
}
prevElement = a[i];
}

return new int[] {minSumElement1, minSumElement2};
}
``````

Here's some test code, with the corner cases from OP's question:

``````private static void test(int minSumIndex1, int minSumIndex2, int... input) {
int[] result = minimumSumOfNonAcjacentElements(input);
if (result[0] == minSumIndex1 && result[1] == minSumIndex2) {
// ok
} else {
throw new AssertionError("Expected: " + minSumIndex1 + ", " + minSumIndex2 + ". Actual=" + Arrays.toString(result));
}
}

public static void main(String[] args) throws Exception {
test(2, 2, 4, 2, 1, 2, 4);
test(1, 2, 2, 2, 1, 2, 4, 2, 6);
test(1, 2, 0, 2, 1, 2, 4, 2, 0);
System.out.println("All tests passed.");
}
``````
-

Use dynamic programming.

1. Remove or disregard the first and last elements of your array. Since they cannot participate in the solution, they are not important. Once you've done this, you can also ignore the "must not be the first or last element" constraint since we've already accounted for it.
2. Find the solution for the first three elements of (what's left of) the array (and without considering the "no first/last element" rule). There is only one solution in this case (`array[0] + array[2]`), so this is a trivial step.
3. Memoize the minimal element which is not the last element (i.e. `min(array[0], array[1])`).
4. Find the solution for the first four elements. We don't have to redo the whole problem; instead we just have to ask whether introducing the fourth element allows us to produce a smaller solution. We can do this by adding the fourth element to the minimal element we memoized in the previous step, and comparing the sum to the solution we found in the second step.
5. Update the memoized minimal element so that it is the minimum of the first three elements.
6. Continue widening and updating in this fashion until we have considered the entire array.

The whole algorithm is O(n), since both widening and updating are constant-time operations. The algorithm can be proved correct by simple induction. O(n) is also a lower bound since we have to consider every element of the array, so this algorithm is optimal.

-
The smallest array that adheres to the constraints in the OP has a length of 5. But that shouldn't affect your general approach. – Reti43 Feb 5 at 12:11
@Reti43: Fixed, thanks. – Kevin Feb 5 at 16:38

Algorithm:

1. Find the minimum, avoiding the end indices. (1 O(n) pass)
2. Find the minimum, avoiding the end indices and the index of (1) and adjacent indices. (1 O(n) pass)
3. Find the minimum, avoiding the end indices and the index of (1) (1 O(n) pass)
4. Find the minimum, avoiding the end indices and the index of (3) and adjacent indices. (1 O(n) pass)
5. Return the minimum of the sums (1) + (2), (3) + (4), if they exist.

Passes 3 and 4 are meant to pass the case [4, 2, 1, 2, 4] = 4 by finding both 2s.

``````public static int minSumNonAdjNonEnd(int[] array)
{
// 1. Find minimum
int minIdx1 = -1;
int minValue1 = Integer.MAX_VALUE;
for (int i = 1; i < array.length - 1; i++)
{
if (array[i] < minValue1)
{
minIdx1 = i;
minValue1 = array[i];
}
}
// 2. Find minimum not among (1) or adjacents.
int minIdx2 = -1;
int minValue2 = Integer.MAX_VALUE;
for (int i = 1; i < array.length - 1; i++)
{
if ((i < minIdx1 - 1 || i > minIdx1 + 1) && (array[i] < minValue2))
{
minIdx2 = i;
minValue2 = array[i];
}
}
boolean sum1Exists = (minIdx1 > -1 && minIdx2 > -1);
int sum1 = minValue1 + minValue2;

// 3. Find minimum not among (1).
int minIdx3 = -1;
int minValue3 = Integer.MAX_VALUE;
for (int i = 1; i < array.length - 1; i++)
{
if ((i != minIdx1) && (array[i] < minValue3))
{
minIdx3 = i;
minValue3 = array[i];
}
}

// 4. Find minimum not among(3) or adjacents.
int minIdx4 = -1;
int minValue4 = Integer.MAX_VALUE;
for (int i = 1; i < array.length - 1; i++)
{
if ((i < minIdx3 - 1 || i > minIdx3 + 1) && (array[i] < minValue4))
{
minIdx4 = i;
minValue4 = array[i];
}
}
boolean sum2Exists = (minIdx3 > -1 && minIdx4 > -1);
int sum2 = minValue3 + minValue4;

if (sum1Exists)
{
if (sum2Exists)
return Math.min(sum1, sum2);
else
return sum1;
}
else
{
if (sum2Exists)
return sum2;
else
throw new IllegalArgumentException("impossible");
}
}
``````

This performs 4 linear searches, for a complexity of O(n).

Test cases:

``````System.out.println(minSumNonAdjNonEnd(new int[] {5, 2, 4, 6, 3, 7}));
System.out.println(minSumNonAdjNonEnd(new int[] {1, 2, 3, 3, 2, 1}));
System.out.println(minSumNonAdjNonEnd(new int[] {4, 2, 1, 2, 4}));
System.out.println(minSumNonAdjNonEnd(new int[] {2, 2, 1, 2, 4, 2, 6}));
System.out.println(minSumNonAdjNonEnd(new int[] {2, 2, 3, 2}));

5
4
4
3
Exception in thread "main" java.lang.IllegalArgumentException: impossible
``````
-

I don't know if my solution is correct because I just tested it with the data in the OP, and I don't even know if this is better or worse than the other ideas but I wanted to try it.

``````static void printMinimalSum(int[] A) {
// Looking for mins so we init this with max value
int[] mins = new int[]{Integer.MAX_VALUE, Integer.MAX_VALUE, Integer.MAX_VALUE};
// Indices, used just to print the solution
int[] indices = new int[]{-1, -1, -1};
// If the array has length 5 then there's only one solution with the 2nd and 4th elements
if (A.length == 5) {
mins[0] = A[1];
indices[0] = 1;
mins[1] = A[3];
indices[1] = 3;
} else {
// Loop on the array without considering the first and the last element
for (int i = 1; i < A.length - 1; i++) {
// We consider each element which is smaller than its neighbours
if ((i == 1 && A[i] < A[i + 1]) // 1: first element, compare it with the second one
|| (i == A.length - 2 && A[i] < A[i - 1]) // 2: last element, compare it with the previous one
|| (A[i] < A[i + 1] && A[i] < A[i - 1])) { // 3: mid element, compare it with both neighbors
// If the element is "legal" then we see if it's smaller than the 3 already saved
if (A[i] < mins[0]) {
mins[0] = A[i];
indices[0] = i;
} else if (A[i] < mins[1]) {
mins[1] = A[i];
indices[1] = i;
} else if (A[i] < mins[2]) {
mins[2] = A[i];
indices[2] = i;
}
}
}
}
// Compute the 3 sums between those 3 elements
int[] sums = new int[]{Math.abs(mins[0]+mins[1]), Math.abs(mins[0]+mins[2]), Math.abs(mins[1]+mins[2])};
// Find the smaller sum and print it
if (sums[0] < sums[1] || sums[0] < sums[2]){
System.out.println("Sum = " + sums[0] + " (elements = {" + mins[0] + "," + mins[1] + "}, indices = {" + indices[0] + "," + indices[1] + "}");
} else if (sums[1] < sums[0] || sums[1] < sums[2]){
System.out.println("Sum = " + sums[1] + " (elements = {" + mins[0] + "," + mins[2] + "}, indices = {" + indices[0] + "," + indices[2] + "}");
} else {
System.out.println("Sum = " + sums[2] + " (elements = {" + mins[1] + "," + mins[2] + "}, indices = {" + indices[1] + "," + indices[2] + "}");
}
}

public static void main(String[] args) {
printMinimalSum(new int[]{5, 2, 4, 6, 3, 7});
printMinimalSum(new int[]{1, 2, 3, 3, 2, 1});
printMinimalSum(new int[]{4, 2, 1, 2, 4});
printMinimalSum(new int[]{2, 2, 1, 2, 4, 2, 6});
}
``````

Output is:

``````Sum = 5 (elements = {2,3}, indices = {1,4}
Sum = 4 (elements = {2,2}, indices = {1,4}
Sum = 4 (elements = {2,2}, indices = {1,3}
Sum = 3 (elements = {1,2}, indices = {2,5}
``````

which seems fine.

-

edit: you're right, I completely ignored the adjacency constraint. luckily I've thought of a solution. The algorithm goes like this:

1. You run once over the array to find the smallest `(O(n))`
2. You run a second time to find the second smallest `(O(n))`
3. If second smallest is not adjacent to smallest we're done(`O(1)` - just an index check)
4. Otherwise run a third time to find third smallest (still `O(n)`)
5. If not adjacent to smallest return smallest and third smallest otherwise return second and third smallest
-
Link-only answers are not helpful in StackOverflow - let alone that this doesn't solve my problem because of the constraints. Please re-read the question – Idos Feb 4 at 19:28
While this link may answer the question, it is better to include the essential parts of the answer here and provide the link for reference. Link-only answers can become invalid if the linked page changes. - From Review – John Hascall Feb 4 at 20:02
The OP has already tried this approach which doesn't necessarily work for the array `A = [2, 2, 1, 2, 4, 2, 6]`. – David Yee Feb 4 at 20:19

Elaborating on the above answer, you'd need a modified insertion-sort to track the smallest four values and the corresponding indexes (an array of 4 elements for each).

Once found the solution would be the first pair whose difference in indexes would be more than 1 and whose sum is the least.

The solution being one of `(0,1)` or `(0,2)` or `(0,3)` or `(1,2)` or `(1,3)` or `(2,3)` where the values indicate the indexes of the array that in turn tracks the position of the actual elements in the array.

Also you'd need to handle the special case for array-length `5` (`arr\[1]+arr[3]`) and an error for those arrays less than `5`.

-

I think this should work:

Find the minimum 3 element and their indices. Since all of them can't be adjacent choose 2 among them.

If all of them are adjacent and the minimum number is in the middle of them, iterate through all elements, find the forth minimum element, choose minimum of `min1+min4`, `min2+min3`, whichever is smaller.

You can do this in one iteration too.

-
This was literally one of my attemps... Please read the question :/ – Idos Feb 4 at 19:33

I have used dynamic programming to solve it.

Idea is to first create the array which tracks the minimum found till now as below: Input array = `[1, 3, 0, 5, 6]` Minimum array = `[1, 1, 0, 0, 0]`

Now using the minimum array and the input array we can use below:

``````DP[i] = min(DP[i-1], min(first_data, second_data))
``````

where `DP[i]` means the minimum found till now which is sum of two previous alternate elements.

`first_data` = sum of `current` element in input array + sum of `current-2` element in minimum array

`second_data` = sum of `current-1` element in input array + sum of `current-3` element in minimum array

``````    import random
def get_min(numbers):
#disregard the first and last element
numbers = numbers[1:len(numbers)-1]
#for remembering the past results
DP = [0]*len(numbers)
#for keeping track of minimum till now found
table = [0]*len(numbers)
high_number = 1 << 30

min_number = numbers[0]
table[0] = min_number
for i in range(0, len(numbers)):
DP[i] = high_number
for i in range(1, len(numbers)):
if numbers[i] < min_number:
min_number = numbers[i]
table[i] = numbers[i]
else:
table[i] = min_number
for i in range(0, len(numbers)):
min_first, min_second = high_number, high_number
if i >= 2:
min_first = numbers[i] + table[i-2]
if i >= 3:
min_second = numbers[i-1] + table[i-3]
if i >= 1:
DP[i] = min(min(DP[i-1], min_first), min_second)
return DP[len(numbers)-1]

input = random.sample(range(100), 10)
print(input)
print(get_min(input))
``````
-

How about that: you find `k` smallest numbers (or more precisely their indices) (`k` big enough, let say `10`). It is sure, that the wanted pair is between them. Now you just check the possible `50` pairs and select the best which satisfies the constraints.

You don't need `10`, less would do - but more than `3` :)

Edit: finding `k` smallest numbers is `O(n)`, because you just keep the best `10` for example in a heap (add new element, delete maximum `O(k*logk)=O(1)` operations).

Then there will be a pair which satisfy the constraints (not next to each other). It is also clear that, if you build the sum with an element not from those `k`, it would be bigger than the best pair chosen from those `k` elements.

Checking at most `k*k` pairs is also `O(1)`, thus the whole running time is `O(n)`.

-
This doesn't guarantee either. – smttsp Feb 4 at 19:36
There are no permutation involved, to find k smallest number out of n elements you need 10*n operations. And than there are only k*(k-1)/2 pairs. – ead Feb 4 at 19:37