# Programming Test - Codility - Dominator

I just had a codility problem give me a hard time and I'm still trying to figure out how the space and time complexity constraints could have been met.

The problem is as follows: A dominant member in the array is one that occupies over half the positions in the array, for example:

{3, 67, 23, 67, 67}

67 is a dominant member because it appears in the array in 3/5 (>50%) positions.

Now, you are expected to provide a method that takes in an array and returns an index of the dominant member if one exists and -1 if there is none.

Easy, right? Well, I could have solved the problem handily if it were not for the following constraints:

• Expected time complexity is O(n)
• Expected space complexity is O(1)

I can see how you could solve this for O(n) time with O(n) space complexities as well as O(n^2) time with O(1) space complexities, but not one that meets both O(n) time and O(1) space.

I would really appreciate seeing a solution to this problem. Don't worry, the deadline has passed a few hours ago (I only had 30 minutes), so I'm not trying to cheat. Thanks.

-
what language were you using? – Kyle Sep 14 '12 at 2:38
I was using java. – Matthias Sep 14 '12 at 2:39
I am really curious about what questions like really tests ? I've been working for 5 years as a Java Developer - mostly developing enterprise systems - not once I actually needed to solve problems like this one ! – Adelin Mar 20 at 14:57
To pass such interview questions I think you have to be some kind of programming competitor and spend like more than 30% of your time solving such problems, what do you think ? – Adelin Mar 20 at 15:01
You're right, solving these kind of problems is certainly a practiced skill. I'm sure that with time, the industry will wake up to the fact that these tests are not really that useful for determining programming aptitude. – Matthias Mar 22 at 11:39

Find the median with BFPRT, aka median of medians (O(N) time, O(1) space). Then scan through the array -- if one number dominates, the median will be equal to that number. Walk through the array and count the number of instances of that number. If it's over half the array, it's the dominator. Otherwise, there is no dominator.

-
Thanks, I understand it now. Still, I can't imagine that many programmers would manage this without knowing that algorithm. This problem was rated 'easy' by codility. – Matthias Sep 14 '12 at 3:46
@Matthias: It depends on what you use. In Java is probably is pretty hard (and even if you know the right algorithm, coding it up in half an hour probably non-trivial). In C++, it's almost ridiculously trivial because the standard library already has the right algorithms (`std::nth_element` and `std::count`) so most of the job is done in two lines of code (caveat: `nth_element` could also use QuickSelect, which is linear on average, but quadratic worst case). – Jerry Coffin Sep 14 '12 at 3:52
although this is an interesting answer to the question, i believe the other more popular answer gets the vote for me. The main reason being that it is more simpler to understand. – JarJarrr Sep 9 '15 at 21:49

Googled "computing dominant member of array", it was the first result. See the algorithm described on page 3.

``````element x;
int count ← 0;
For(i = 0 to n − 1) {
if(count == 0) { x ← A[i]; count++; }
else if (A[i] == x) count++;
else count−−;
}
Check if x is dominant element by scanning array A
``````

Basically observe that if you find two different elements in the array, you can remove them both without changing the dominant element on the remainder. This code just keeps tossing out pairs of different elements, keeping track of the number of times it has seen the single remaining unpaired element.

-
Thanks for that. – Matthias Sep 14 '12 at 3:49
this is the smartest answer – Gisway May 10 '13 at 7:06
@Rob: I didn't figure it out, I just searched for it. Someone smart figured it out for me. Kind of like most of human progress... – Keith Randall Sep 22 '13 at 16:53
@SonicSoul: no, this algorithm finds x. If there is a dominant element, x is guaranteed to be set to it at the end of the loop. Since x occurs more than n/2 times, you increment the count more than decrementing it, so it can't end up at 0. – Keith Randall May 4 '15 at 14:07
@SonicSoul: Yes, your final sentence is correct. The final `count` is not the # of appearances of `x`. Ignore the final count. You need to iterate through the array again and count occurrences of `x`. p.s. 3 is not a dominant element in your example. It needs to appear >n/2 times, not ==n/2 times. – Keith Randall May 4 '15 at 16:29

Adding a Java 100/100 O(N) time with O(1) space:

https://codility.com/demo/results/demoPNG8BT-KEH/

``````class Solution {
public int solution(int[] A) {
int indexOfCandidate = -1;
int stackCounter = 0, candidate=-1, value=-1, i =0;

for(int element: A ) {
if (stackCounter == 0) {
value = element;
++stackCounter;
indexOfCandidate = i;
} else {
if (value == element) {
++stackCounter;
} else {
--stackCounter;
}
}
++i;
}

if (stackCounter > 0 ) {
candidate = value;
} else {
return -1;
}

int countRepetitions = 0;
for (int element: A) {
if( element == candidate) {
++countRepetitions;

}
if(countRepetitions > (A.length / 2)) {
return indexOfCandidate;
}
}
return -1;
}
}
``````

If you want to see the Java source code it's here, I added some test cases as comments as the beginning of the file.

-

Here's my C solution which scores 100%

``````int solution(int A[], int N) {

int candidate;
int count = 0;
int i;

// 1. Find most likely candidate for the leader
for(i = 0; i < N; i++){

// change candidate when count reaches 0
if(count == 0) candidate = i;

// count occurrences of candidate
if(A[i] == A[candidate]) count++;
else count--;
}

// 2. Verify that candidate occurs more than N/2 times
count = 0;
for(i = 0; i < N; i++) if(A[i] == A[candidate]) count++;

if (count <= N/2) return -1;
return candidate; // return index of leader
}
``````
-

Java solution with score 100%

``````public  int solution(int[] array) {

int candidate=0;
int counter = 0;

for(int i=0; i<array.length; i++){

if(counter == 0) candidate = i;

if(array[i] == array[candidate]){
counter++;
}else {
counter--;
}
}

// Count candidate occurrences in array
counter = 0;
for(int i=0; i<array.length; i++){
if(array[i] == array[candidate]) counter++;
}

// Check that candidate occurs more than array.lenght/2
return counter>array.length/2 ? candidate : -1;
}
``````
-

Does it have to be a particularly good algorithm? ;-)

``````static int dominant(final int... set) {
final int[] freqs = new int[Integer.MAX_VALUE];
for (int n : set) {
++freqs[n];
}
int dom_freq = Integer.MIN_VALUE;
int dom_idx = -1;
int dom_n = -1;
for (int i = set.length - 1; i >= 0; --i) {
final int n = set[i];
if (dom_n != n) {
final int freq = freqs[n];
if (freq > dom_freq) {
dom_freq = freq;
dom_n = n;
dom_idx = i;
} else if (freq == dom_freq) {
dom_idx = -1;
}
}
}
return dom_idx;
}
``````

(this was primarily meant to poke fun at the requirements)

-
Haha! Nice one :) – Matthias Sep 14 '12 at 3:48

In python, we are lucky some smart people have bothered to implement efficient helpers using C and shipped it in the standard library. The collections.Counter is useful here.

``````>>> data = [3, 67, 23, 67, 67]
>>> from collections import Counter
>>> counter = Counter(data)  # counter accepts any sequence/iterable
>>> counter  # dict like object, where values are the occurrence
Counter({67: 3, 3: 1, 23: 1})
>>> common = counter.most_common()[0]
>>> common
(67, 3)
>>> common[0] if common[1] > len(data) / 2.0 + 1 else -1
67
>>>
``````

If you prefer a function here is one ...

``````>>> def dominator(seq):
counter = Counter(seq)
common = counter.most_common()[0]
return common[0] if common[1] > len(seq) / 2.0 + 1 else -1
...
>>> dominator([1, 3, 6, 7, 6, 8, 6])
-1
>>> dominator([1, 3, 6, 7, 6, 8, 6, 6])
6
``````
-
Counter uses O(n) space irrespective of whether it's implemented by the standard library of the language or not. – Chandranshu Oct 19 '13 at 7:58

This question looks hard if a small trick does not come to the mind :). I found this trick in this document of codility : https://codility.com/media/train/6-Leader.pdf.

The linear solution is explained at the bottom of this document.

I implemented the following java program which gave me a score of 100 on the same lines.

``````public int solution(int[] A) {

Stack<Integer> stack = new Stack<Integer>();

for (int i =0; i < A.length; i++)
{
if (stack.empty())
stack.push(new Integer(A[i]));
else
{
int topElem = stack.peek().intValue();
if (topElem == A[i])
{
stack.push(new Integer(A[i]));
}
else
{
stack.pop();
}
}
}

if (stack.empty())
return -1;

int elem = stack.peek().intValue();
int count = 0;
int index = 0;
for (int i = 0; i < A.length; i++)
{
if (elem == A[i])
{
count++;
index = i;
}
}

if (count > ((double)A.length/2.0))
return index;
else
return -1;
}
``````
-

Consider this 100/100 solution in Ruby:

``````# Algorithm, as described in https://codility.com/media/train/6-Leader.pdf:
#
# * Iterate once to find a candidate for dominator.
# * Count number of candidate occurences for the final conclusion.
def solution(ar)
n_occu = 0
candidate = index = nil

ar.each_with_index do |elem, i|
if n_occu < 1
# Here comes a new dominator candidate.
candidate = elem
index = i
n_occu += 1
else
if candidate == elem
n_occu += 1
else
n_occu -= 1
end
end # if n_occu < 1
end

# Method result. -1 if no dominator.
# Count number of occurences to check if candidate is really a dominator.
if n_occu > 0 and ar.count {|_| _ == candidate} > ar.size/2
index
else
-1
end
end

#--------------------------------------- Tests

def test
sets = []
sets << ["4666688", [1, 2, 3, 4], [4, 6, 6, 6, 6, 8, 8]]
sets << ["333311", [0, 1, 2, 3], [3, 3, 3, 3, 1, 1]]
sets << ["313131", [-1], [3, 1, 3, 1, 3, 1]]
sets << ["113333", [2, 3, 4, 5], [1, 1, 3, 3, 3, 3]]

sets.each do |name, one_of_expected, ar|
out = solution(ar)
raise "FAILURE at test #{name.inspect}: #{out.inspect} not in #{expected.inspect}" if not one_of_expected.include? out
end

puts "SUCCESS: All tests passed"
end
``````
-

Here is an easy to read, 100% score version in Objective-c

``````  if (A.count > 100000)
return -1;
NSInteger occur = 0;
NSNumber *candidate = nil;
for (NSNumber *element in A){
if (!candidate){
candidate = element;
occur = 1;
continue;
}

if ([candidate isEqualToNumber:element]){
occur++;
}else{
if (occur == 1){
candidate = element;
continue;
}else{
occur--;
}
}
}
if (candidate){
occur = 0;
for (NSNumber *element in A){
if ([candidate isEqualToNumber:element])
occur++;
}
if (occur > A.count / 2)
return [A indexOfObject:candidate];
}
return -1;
``````
-

100% score JavaScript solution. Technically it's O(nlogn) but still passed.

``````function solution(A) {
if (A.length == 0)
return -1;

var S = A.slice(0).sort(function(a, b) {
return a - b;
});

var domThresh = A.length/2;
var c = S[Math.floor(domThresh)];
var domCount = 0;

for (var i = 0; i < A.length; i++) {
if (A[i] == c)
domCount++;

if (domCount > domThresh)
return i;
}

return -1;
}
``````
-

This is the solution in VB.NET with 100% performance.

``````Dim result As Integer = 0
size = A.Length
If size > 0 Then

For i = 1 To size - 1
Else
Else
End If
End If
Next
valCount = 0
For i = 0 To size - 1
valCount += 1
End If
Next
If valCount <= size / 2 Then
result = 0
Else
For i = 0 To size - 1
valCount -= 1
End If
If LadderCount > (LadderCount + 1) / 2 And (valCount > (size - (i + 1)) / 2) Then
result += 1
End If
Next
End If
End If
Return result
``````

See the correctness and performance of the code

-

Below solution resolves in complexity O(N).

``````public int solution(int A[]){
int dominatorValue=-1;
if(A != null && A.length>0){
Hashtable<Integer, Integer> count=new Hashtable<>();
dominatorValue=A[0];
int big=0;
for (int i = 0; i < A.length; i++) {
int value=0;
try{
value=count.get(A[i]);
value++;
}catch(Exception e){
}
count.put(A[i], value);
if(value>big){
big=value;
dominatorValue=A[i];
}
}
}
return dominatorValue;
}
``````
-
``````function solution(\$A){

if (empty(\$A)) return -1;

\$copy = array_count_values(\$A);  // 3 => 7, value => number of repetition

\$max_repetition = max(\$copy); // at least 1 because the array is not empty

\$dominator = array_search(\$max_repetition, \$copy);

if (\$max_repetition > count(\$A) / 2) return array_search(\$dominator, \$A); else return -1;

}
``````
-

100%

``````import java.util.HashMap;
import java.util.Map;

class Solution {
public static int solution(int[] A) {
final int N = A.length;
Map<Integer, Integer> mapOfOccur = new HashMap((N/2)+1);

for(int i=0; i<N; i++){
Integer count = mapOfOccur.get(A[i]);
if(count == null){
count = 1;
mapOfOccur.put(A[i],count);
}else{
mapOfOccur.replace(A[i], count, ++count);
}
if(count > N/2)
return i;

}
return -1;
}
}
``````
-
You made a map. Space complexity is not O(1) – cricket_007 Mar 21 at 22:55

I think this question has already been resolved somewhere. The "official" solution should be :

``````  public int dominator(int[] A) {
int N = A.length;

for(int i = 0; i< N/2+1; i++)
{
int count=1;
for(int j = i+1; j < N; j++)
{
if (A[i]==A[j]) {count++; if (count > (N/2)) return i;}
}
}

return -1;
}
``````
-
this solution required a sorted array. – Cooper.Wu Apr 29 '13 at 23:49
I suppose this solution's time complexity is far beyond O(N). – dadooda Jan 24 '14 at 21:57

How about sorting the array first? You then compare middle and first and last elements of the sorted array to find the dominant element.

``````public Integer findDominator(int[] arr) {
int[] arrCopy = arr.clone();

Arrays.sort(arrCopy);

int length = arrCopy.length;
int middleIndx = (length - 1) /2;

int middleIdxRight;
int middleIdxLeft = middleIndx;

if (length % 2 == 0) {
middleIdxRight = middleIndx+1;
} else {
middleIdxRight = middleIndx;
}

if (arrCopy[0] == arrCopy[middleIdxRight]) {
return arrCopy[0];
}

if (arrCopy[middleIdxLeft] == arrCopy[length -1]) {
return arrCopy[middleIdxLeft];
}

return null;
}
``````
-
Arrays.sort(arrCopy); is `O(n)` in the best case, and `O(n * log n)' in general case. Moreover returned indexes doesn't match with the original indexes. – Anton Boritskiy Oct 6 '12 at 22:18

C#

``````int dominant = 0;
int repeat = 0;
int? repeatedNr = null;
int maxLenght = A.Length;
int halfLenght = A.Length / 2;
int[] repeations = new int[A.Length];

for (int i = 0; i < A.Length; i++)
{
repeatedNr = A[i];
for (int j = 0; j < A.Length; j++)
{
if (repeatedNr == A[j])
{
repeations[i]++;
}
}
}
repeatedNr = null;
for (int i = 0; i < repeations.Length; i++)
{
if (repeations[i] > repeat)
{
repeat = repeations[i];
repeatedNr = A[i];
}
}
if (repeat > halfLenght)
dominant = int.Parse(repeatedNr.ToString());
``````
-
this is not O(N) time, O(1) space – Gisway May 10 '13 at 7:04
``````class Program
{
static void Main(string[] args)
{
int []A= new int[] {3,6,2,6};
int[] B = new int[A.Length];
Program obj = new Program();
obj.ABC(A,B);

}

public int ABC(int []A, int []B)
{
int i,j;

int n= A.Length;
for (j=0; j<n ;j++)
{
int count = 1;
for (i = 0; i < n; i++)
{
if ((A[j]== A[i] && i!=j))
{
count++;

}

}
int finalCount = count;
B[j] = finalCount;// to store the no of times a number is repeated

}
// int finalCount = count / 2;
int finalCount1 = B.Max();// see which number occurred max times
if (finalCount1 > (n / 2))

else
{ Console.WriteLine("no number found"); Console.ReadLine(); }
return -1;
}
}
``````
-
-1: This neither conforms to the time nor the space requirements. – Daniel Hilgarth Sep 23 '13 at 13:29

In Ruby you can do something like

``````def dominant(a)
hash = {}
0.upto(a.length) do |index|
element = a[index]
hash[element] = (hash[element] ? hash[element] + 1 : 1)
end

res = hash.find{|k,v| v > a.length / 2}.first rescue nil
res ||= -1
return res
end
``````
-
What about this requirement: "expected worst-case space complexity is O(1)"? Proposed solution's space complexity is at least O(N), not to mention it's an associative hash. – dadooda Jan 24 '14 at 21:46

This is my answer in Java: I store a count in seperate array which counts duplicates of each of the entries of the input array and then keeps a pointer to the array position that has the most duplicates. This is the dominator.

``````private static void dom(int[] a) {
int position = 0;
int max = 0;
int score = 0;
int counter = 0;
int[]result = new int[a.length];

for(int i = 0; i < a.length; i++){
score = 0;
for(int c = 0; c < a.length;c++){

if(a[i] == a[c] && c != i ){
score = score + 1;
result[i] = score;
if(result[i] > position){
position = i;
}
}

}
}

//This is just to facilitate the print function and MAX = the number of times that dominator number was found in the list.

for(int x = 0 ; x < result.length-1; x++){
if(result[x] > max){
max = result[x] + 1;
}

}

System.out.println(" The following number is the dominator " + a[position] +  " it appears a total of " + max);

}
``````
-
It needs to be O(N) – gran_profaci Aug 15 '13 at 21:21