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Is there any method to remove the duplicate elements in an array in place in C/C++ in O(n)? Suppose elements are a[5]={1,2,2,3,4} then resulting array should contain {1,2,3,4} The solution can be achieved using two for loops but that would be O(n^2) I believe.

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If the array is necessarily sorted, you can get away quite easily. –  zneak Aug 8 '10 at 1:42
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You are either using C, or you are using C++. Pick one. –  Greg Hewgill Aug 8 '10 at 1:49
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@Greg Hewgill: it's quite possible that if OP is just out of college, both look the same. –  zneak Aug 8 '10 at 2:17
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@William Pursell: except if it's the case he doesn't know how to pick one of the two. –  zneak Aug 8 '10 at 6:50
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@pranay: I mean take the loop referenced in the article I posted, remove the template stuff, and change "ForwardIterator" to some iterator or pointer type, and you're done. –  Billy ONeal Aug 10 '10 at 13:16
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7 Answers

up vote 8 down vote accepted

If, and only if, the source array is sorted, this can be done in linear time:

std::unique(a, a + 5); //Returns a pointer to the new logical end of a.

Otherwise you'll have to sort first, which is (99.999% of the time) n lg n.

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Just not true. Look at my answer. –  Borealid Aug 8 '10 at 1:44
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Sorting isn't necessarily n lg n. Depending on the data, there might be O(n) sorts available (e.g. counting sort, bucket sort). –  jamesdlin Aug 8 '10 at 1:44
    
@Borealid: See my comment on your answer. @Jamesdin: True, but A. most such sorts don't perform well in practice, and B. I was assuming use of std::sort, which is a comparison sort. –  Billy ONeal Aug 8 '10 at 2:17
    
In-place means the only efficient sort available is heap sort. Everything else is O(n^2) or non-constant space. Most have both problems. –  R.. Aug 8 '10 at 3:36
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@R. std::sort is in place and n lg n. It's usually a form of Introsort. –  Billy ONeal Aug 8 '10 at 3:40
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Best case is O(n log n). Perform a heap sort on the original array: O(n log n) in time, O(1)/in-place in space. Then run through the array sequentially with 2 indices (source & dest) to collapse out repetitions. This has the side effect of not preserving the original order, but since "remove duplicates" doesn't specify which duplicates to remove (first? second? last?), I'm hoping that you don't care that the order is lost.

If you do want to preserve the original order, there's no way to do things in-place. But it's trivial if you make an array of pointers to elements in the original array, do all your work on the pointers, and use them to collapse the original array at the end.

Anyone claiming it can be done in O(n) time and in-place is simply wrong, modulo some arguments about what O(n) and in-place mean. One obvious pseudo-solution, if your elements are 32-bit integers, is to use a 4-gigabit bit-array (512 megabytes in size) initialized to all zeros, flipping a bit on when you see that number and skipping over it if the bit was already on. Of course then you're taking advantage of the fact that n is bounded by a constant, so technically everything is O(1) but with a horrible constant factor. However, I do mention this approach since, if n is bounded by a small constant - for instance if you have 16-bit integers - it's a very practical solution.

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Unicode code points (20.1 bit) are another case where the bit-array solution would be very practical - for example if you want to get a list of which characters are used in a text. In such a case, the bit-array might even be the ideal form for the final output. –  R.. Aug 8 '10 at 3:58
    
_ Anyone claiming it can be done in O(n) time and in-place is simply wrong, modulo some arguments about what O(n) and in-place mean_ If you have proof, the CS journals are waiting on your brilliant insight. –  user382751 Aug 8 '10 at 4:15
    
I don't have proof, just like nobody has proof that factoring huge numbers can't be done efficiently. I'd like to turn your challenge around: if anyone here has an O(n) time and in-place solution, the CS journals are waiting for their brilliant insight. In the mean time, I'm going to assume they're wrong. –  R.. Aug 8 '10 at 4:21
    
To clarify: proving it impossible, although impressive for its difficulty, would not revolutionize anything; it would just confirm what everyone already believes intuitively. On the other hand, an efficient solution (to either problem I mentioned) would revolutionize computing. –  R.. Aug 8 '10 at 4:37
    
Factoring, yes, removing duplicates on the unit-cost RAM in O(n) time with O(1) extra space, no. –  user382751 Aug 8 '10 at 4:56
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Yes. Because access (insertion or lookup) on a hashtable is O(1), you can remove duplicates in O(N).

Pseudocode:

hashtable h = {}
numdups = 0
for (i = 0; i < input.length; i++) {
    if (!h.contains(input[i])) {
        input[i-numdups] = input[i]
        h.add(input[i])
    } else {
        numdups = numdups + 1
    }

This is O(N).

Some commenters have pointed out that whether a hashtable is O(1) depends on a number of things. But in the real world, with a good hash, you can expect constant-time performance. And it is possible to engineer a hash that is O(1) to satisfy the theoreticians.

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"Assuming noncolliding hash" is a very bold statement. –  zneak Aug 8 '10 at 1:45
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The O(1) complexity of a hashtable lookup/insertion is not contingent on a non-colliding hash function. (As per the birthday paradox, collisions will happen, quickly: that is for table of size m, when around log(m) elements have been inserted---with good probability.) The O(1) complexity is based off a combination of things: a reasonably good (close to uniform, without being collision-free) hash function and the ability to dynamically resize the table at small (eventually amortized) cost. –  Jérémie Aug 8 '10 at 2:02
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@Borealid: Your algorithm is worst case quadratic. Mine is worst case n lg n. Claiming your algorithm is always linear time is simply incorrect, though with a good hash it will be linear in the average case. But in algorithm design, we're usually talking about worst case, not best case, performance. –  Billy ONeal Aug 8 '10 at 2:16
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-1 because the question explicitly specifies in place. This algorithm is not. –  Billy ONeal Aug 8 '10 at 2:18
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-1 for wrong answer. Hash table is not O(1) and does not remotely resemble in-place. –  R.. Aug 8 '10 at 3:21
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I'm going to suggest a variation on Borealids answer, but I'll point out up front that it's cheating. Basically, it only works assuming some severe constraints on the values in the array - e.g. that all keys are 32-bit integers.

Instead of a hash table, the idea is to use a bitvector. This is an O(1) memory requirement which should in theory keep Rahul happy (but won't). With the 32-bit integers, the bitvector will require 512MB (ie 2**32 bits) - assuming 8-bit bytes, as some pedant may point out.

As Borealid should point out, this is a hashtable - just using a trivial hash function. This does guarantee that there won't be any collisions. The only way there could be a collision is by having the same value in the input array twice - but since the whole point is to ignore the second and later occurences, this doesn't matter.

Pseudocode for completeness...

src = dest = input.begin ();
while (src != input.end ())
{
  if (!bitvector [*src])
  {
    bitvector [*src] = true;
    *dest = *src; dest++;
  }
  src++;
}
//  at this point, dest gives the new end of the array

Just to be really silly (but theoretically correct), I'll also point out that the space requirement is still O(1) even if the array holds 64-bit integers. The constant term is a bit big, I agree, and you may have issues with 64-bit CPUs that can't actually use the full 64 bits of an address, but...

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+1 :-D I like this. –  Borealid Aug 8 '10 at 20:53
    
Described by R.. 7 hours earlier. stackoverflow.com/questions/3432760/… –  Ben Voigt Aug 11 '10 at 23:42
    
Yes - and I definitely read that post, though not (that I remember) all of it. I plead human fallibility. –  Steve314 Aug 13 '10 at 0:16
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Take your example. If the array elements are bounded integer, you can create a lookup bitarray.

If you find an integer such as 3, turn the 3rd bit on. If you find an integer such as 5, turn the 5th bit on.

If the array contains elements rather than integer, or the element is not bounded, using a hashtable would be a good choice, since hashtable lookup cost is a constant.

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Hashtable lookup cost is O(n) not O(1), unless you have constraints on the data which ensure a bound on the number of collisions. Expected performance is constant-time, but big-O means worst case by definition. –  R.. Aug 8 '10 at 3:35
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@R: Big-O notation does not refer to worst case. ... the worst case or average case running time or memory usage of an algorithm is often expressed as a function of the length of its input using big-O notation... See wiki en.wikipedia.org/wiki/Big_O_notation. –  SiLent SoNG Aug 8 '10 at 6:14
    
@R: In practice, some data structure has O(N) in worst case, but it has amortized average cost of O(1), it is still considered good. An example is vector: when it grows the cost is O(N) at worst, but on average it is O(1). My point is to show Big-O notation is a measurement of the worst case or average case, not only worst case. –  SiLent SoNG Aug 8 '10 at 6:17
    
You're confusing terms. If you are considering amortized runtime, you still have a worst case and an average case and a best case. Big-Oh by definition deals with the worst case behavior, amortized or not. –  Dennis Zickefoose Aug 8 '10 at 18:42
    
Big-O gives an upper bound for the value of a function. Whether that function represents worst-case or average-case running time (or something else) is not part of the definition of Big-O. –  fgb Mar 25 '12 at 2:12
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The canonical implementation of the unique() algorithm looks like something similar to the following:

template<typename Fwd>
Fwd unique(Fwd first, Fwd last)
{
    if( first == last ) return first;
    Fwd result = first;
    while( ++first != last ) {
        if( !(*result == *first) )
            *(++result) = *first;
    }
    return ++result;
}

This algorithm takes a range of sorted elements. If the range is not sorted, sort it before invoking the algorithm. The algorithm will run in-place, and return an iterator pointing to one-past-the-last-element of the unique'd sequence.

If you can't sort the elements then you've cornered yourself and you have no other choice but to use for the task an algorithm with runtime performance worse than O(n).

This algorithm runs in O(n) runtime. That's big-oh of n, worst case in all cases, not amortized time. It uses O(1) space.

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thank you , that was helpful :) –  pranay Sep 10 '10 at 14:03
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The example you have given is a sorted array. It is possible only in that case (given your constant space constraint)

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What constant space constraint? Does "in-place" imply a space constraint? –  Steve314 Aug 8 '10 at 2:11
    
I consider in-place to imply O(1) space. Otherwise you can just make a copy as temporary storage, do the work in the copy, store it back on top of the original, and call it "in-place". That's bogus. –  R.. Aug 8 '10 at 3:22
    
Not necessarily. First off, what about O(log n) space. Second, updating in-place can still be an optimisation even if you still need O(n) or more extra space. For example, you can create then sort an array of references to your data, then use that to sort your data in-place in O(n) time. The initial sort is still O(n log n), but if swaps of references are substantially quicker than swaps of your data items, this can be beneficial. Space restrictions aren't the only reason for doing updates in-place. –  Steve314 Aug 8 '10 at 8:44
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