Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I was asked an interview question to find the number of distinct absolute values among the elements of the array. I came up with the following solution (in C++) but the interviewer was not happy with the code's run time efficiency.

  1. I will appreciate pointers as to how I can improve the run time efficiency of this code?
  2. Also how do I calculate the efficiency of the code below? The for loop executes A.size() times. However I am not sure about the efficiency of STL find (In the worse case it could be O(n) so that makes this code O(n2) ?

    int absoluteDistinct ( const vector<int> &A ) {
    using namespace std;
    list<int> x;
    vector<int>::const_iterator it;
    for(it = A.begin();it < A.end();it++){
      if(find(x.begin(),x.end(),abs(*it)) == x.end()){
    return x.size();


share|improve this question
thank you for all your answers! –  user7 Aug 21 '11 at 4:27
Fish a day will really not help you. Especially for the interview sake. You need to grab atleast couple of books on Data-structure and algorithm. My personnel beginner favorite is Sahni's "Data-structure and algo in C++" And then go on to read 'data structure using C and C++ ' by langsam/tennenbaum. And as far as questions are concerned, you should know that interviewer are concerned about if YOU can derive bigO. Not if you know. Ppl are concerned about getting upvoted with right answer. They will give you what you WANT. They dont care about the stuff you NEED. –  Ajeet Aug 24 '11 at 23:28
Also pal, please dont assume that just because you have to code it in C++ you HAVE TO use STL algos. They are there for help. If the need be you should be able to customize them. And this question is pretty much that exceptional case when you need to twist the standard algos for efficiency. –  Ajeet Aug 25 '11 at 0:16

11 Answers 11

up vote 3 down vote accepted

std::find() is linear (O(n)). I'd use a sorted associative container to handle this, specifically std::set.

#include <vector>
#include <set>
using namespace std;

int distict_abs(const vector<int>& v)
   std::set<int> distinct_container;

   for(auto curr_int = v.begin(), end = v.end(); // no need to call v.end() multiple times
       curr_int != end;
       // std::set only allows single entries
       // since that is what we want, we don't care that this fails 
       // if the second (or more) of the same value is attempted to 
       // be inserted.

   return distinct_container.size();

There is still some runtime penalty with this approach. Using a separate container incurs the cost of dynamic allocations as the container size increases. You could do this in place and not occur this penalty, however with code at this level its sometimes better to be clear and explicit and let the optimizer (in the compiler) do its work.

share|improve this answer

To propose alternative code to the set code.

Note that we don't want to alter the caller's vector, we take by value. It's better to let the compiler copy for us than make our own. If it's ok to destroy their value we can take by non-const reference.

#include <vector>
#include <algorithm>
#include <iterator>

#include <cstdlib>

using namespace std;

int count_distinct_abs(vector<int> v)
    transform(v.begin(), v.end(), v.begin(), abs); // O(n) where n = distance(v.end(), v.begin())
    sort(v.begin(), v.end()); // Average case O(n log n), worst case O(n^2) (usually implemented as quicksort.
    // To guarantee worst case O(n log n) replace with make_heap, then sort_heap.

    // Unique will take a sorted range, and move things around to get duplicated
    // items to the back and returns an iterator to the end of the unique section of the range
    auto unique_end = unique(v.begin(), v.end()); // Again n comparisons
    return distance(unique_end, v.begin()); // Constant time for random access iterators (like vector's)

The advantage here is that we only allocate/copy once if we decide to take by value, and the rest is all done in-place while still giving you an average complexity of O(n log n) on the size of v.

share|improve this answer
This is much better than using std::set –  john Aug 21 '11 at 5:20
@john Set is the first thing to come to mind, but after a short walk, I realized it was doable in-place, at the same time cost and very short using only stl algos. –  Flame Aug 21 '11 at 5:22
The problem with STL algos is sometime we tend to overuse them. :) IMHO, the best way is to customize the quicksort algorithm such that when we are partitioning whenever we get two equal element then overwrite the second duplicate with last element in the range and then reduce the range. This will ensure you will not process duplicate elements twice. Also after quick sort is done the range of the element is answer. –  Ajeet Aug 25 '11 at 0:05
To comment on my comment. Unique will get rid of consecutive entries. Thus if the range is sorted all duplicates are consecutive and get deleted. –  Flame Sep 19 '11 at 2:26

Yes, this will be O(N2) -- you'll end up with a linear search for each element.

A couple of reasonably obvious alternatives would be to use an std::set or std::unordered_set. If you don't have C++0x, you can replace std::unordered_set with tr1::unordered_set or boost::unordered_set.

Each insertion in an std::set is O(log N), so your overall complexity is O(N log N).

With unordered_set, each insertion has constant (expected) complexity, giving linear complexity overall.

share|improve this answer

Basically, replace your std::list with a std::set. This gives you O(log(set.size())) searches + O(1) insertions, if you do things properly. Also, for efficiency, it makes sense to cache the result of abs(*it), although this will have only a minimal (negligible) effect. The efficiency of this method is about as good as you can get it, without using a really nice hash (std::set uses bin-trees) or more information about the values in the vector.

share|improve this answer

Two points.

  1. std::list is very bad for search. Each search is O(n).

  2. Use std::set. Insert is logarithmic, it removes duplicate and is sorted. Insert every value O(n log n) then use set::size to find how many values.


To answer part 2 of your question, the C++ standard mandates the worst case for operations on containers and algorithms.

Find: Since you are using the free function version of find which takes iterators, it cannot assume anything about the passed in sequence, it cannot assume that the range is sorted, so it must traverse every item until it finds a match, which is O(n).

If you are using set::find on the other hand, this member find can utilize the structure of the set, and it's performance is required to be O(log N) where N is the size of the set.

share|improve this answer

To answer your second question first, yes the code is O(n^2) because the complexity of find is O(n).

You have options to improve it. If the range of numbers is low you can just set up a large enough array and increment counts while iterating over the source data. If the range is larger but sparse, you can use a hash table of some sort to do the counting. Both of these options are linear complexity.

Otherwise, I would do one iteration to take the abs value of each item, then sort them, and then you can do the aggregation in a single additional pass. The complexity here is n log(n) for the sort. The other passes don't matter for complexity.

share|improve this answer

I think a std::map could also be interesting:

int absoluteDistinct(const vector<int> &A) 
    map<int, char> my_map;

    for (vector<int>::const_iterator it = A.begin(); it != A.end(); it++)
        my_map[abs(*it)] = 0;

    return my_map.size();
share|improve this answer

As @Jerry said, to improve a little on the theme of most of the other answers, instead of using a std::map or std::set you could use a std::unordered_map or std::unordered_set (or the boost equivalent).

This would reduce the runtimes down from O(n lg n) or O(n).

Another possibility, depending on the range of the data given, you might be able to do a variant of a radix sort, though there's nothing in the question that immediately suggests this.

share|improve this answer

Sort the list with a Radix style sort for O(n)ish efficiency. Compare adjacent values.

share|improve this answer

The best way is to customize the quicksort algorithm such that when we are partitioning whenever we get two equal element then overwrite the second duplicate with last element in the range and then reduce the range. This will ensure you will not process duplicate elements twice. Also after quick sort is done the range of the element is answer Complexity is still O(n*Lg-n) BUT this should save atleast two passes over the array.

Also savings are proportional to % of duplicates. Imagine if they twist original questoin with, 'say 90% of the elements are duplicate' ...

share|improve this answer

One more approach :

Space efficient : Use hash map . O(logN)*O(n) for insert and just keep the count of number of elements successfully inserted.

Time efficient : Use hash table O(n) for insert and just keep the count of number of elements successfully inserted.

share|improve this answer
Note that hash maps aren't as space efficent as you might think. Especially compared with a plain set<> –  elegant dice Oct 29 '12 at 13:16
by hashMap , I meant a container which uses some sort of tree. That would be pretty space efficient –  Ajeet Oct 29 '12 at 19:30

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.