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 solved this problem by following a straightforward but not optimal algorithm. I sorted the vector in descending order and after that substracted numbers from max to min to see if I get a + b + c = d. Notice that I haven't used anywhere the fact that elements are natural, distinct and 10 000 at most. I suppose these details are the key. Does anyone here have a hint over an optimal way of solving this?

Thank you in advance!

Later Edit: My idea goes like this:

'<<quicksort in descending order>>'

for i:=0 to count { // after sorting, loop through the array
    int d := v[i];
    for j:=i+1 to count {
        int dif1 := d - v[j];
        int a := v[j];

       for k:=j+1 to count {
           if (v[k] > dif1)
              continue;
           int dif2 := dif1 - v[k];
         b := v[k];

    for l:=k+1 to count {
 if (dif2 = v[l]) {
    c := dif2; 
     return {a, b, c, d}
 }
           }
        }
    }
}

What do you think?(sorry for the bad indentation)

share|improve this question
    
Does a, b, c, d have to be different numbers, or can you use the same number several times? –  polygenelubricants Jun 4 '10 at 11:46
    
They have to be different. –  king_kong Jun 4 '10 at 11:57
    
If the numbers are natural (i.e., they run from zero to infinity), you first discard all the numbers greater than d. –  Escualo Jun 4 '10 at 17:12
    
look much like projecteuler.net ;) (where it is kind of forbidden asking those things) –  Ronny Brendel Jun 5 '10 at 9:07
    
Don't know what projecteuler.net is. I'll take a look though. –  king_kong Jun 9 '10 at 17:50
add comment

3 Answers

Solution in O(n2 log n):

Compute sets of all possible sums and differences:

{ai+aj: 1 <= i,j <= n}

{ai-aj: 1 <= i,j <= n}

(store them in a balanced binary search tree) and check if they have a common element. If yes, there are i,j,k,l such that ai + aj = ak - al, that is ai+aj+al=ak.

Solution in O(an log an), where an is the largest number in the vector:

Compute the polynomial

(xa1+xa2 + ... + xan)3

you can do it in O(an log an) using Fast Fourier Transform (first compute square, then third power; see here for description). Observe that after multiplication a coefficient xbi was formed from multiplication xai * xaj * xak= xai+aj+ak for some i,j,k. Check if there is a power xal in the resulting polynomial.

Unfortunately this allows some i,j,k to be used twice. Subtracting 3(x2a1+...+x2an)*(xa1+...+xan) - 2(x3a1+...+x3an) will remove those xai+aj+ak.

share|improve this answer
1  
I was about to post your BST solution, but with hashtable instead. If a < b < c < d is a restriction, then you have to do something extra, because right now you're allowing some numbers to appear twice. –  polygenelubricants Jun 4 '10 at 11:44
    
You can tag the elements in the two trees with indices of elements: {(a_i+a_j, i, j): 1 <= i,j <= n} and {(a_i-a_j, i, j): 1 <= i,j <= n}; when joining the lists, check if the tags are all different. –  sdcvvc Jun 4 '10 at 11:51
2  
If using a hashtable instead of the tree, you could get rid of O(log n) by using the sum/difference as key. After having computed and inserted all (a+b)-sums, you would just have to check for the differences if there is an element -(d-c) in the (a+b) table. That gives a total runtime of O(n^2). –  MicSim Jun 4 '10 at 12:04
    
Assuming you can create a bit array with 2*a_n elements initialized to zero. If not, this solution is O(a_n + n^2). –  sdcvvc Jun 4 '10 at 12:10
1  
This is most likely a 3SUM-Hard problem. In other words, don't look for better than O(N^2) solutions :-) –  Aryabhatta Jun 4 '10 at 16:38
show 2 more comments

There is an algorithm by Shamir and Schroeppel that solves this problem in time O(N^2) and with memory O(N), when N is the number of inputs. It basically is what sdcvvc proposes, but instead of storing the sets {ai + aj} as a whole one would repeatedly compute only the sums in appropriate intervals. This saves memory, but does not increase the time complexity.

Richard Schroeppel, Adi Shamir: "A T=O(2^(n/2)), S=O(2^(n/4)) Algorithm for Certain NP-Complete Problems". SIAM J. Comput. 10(3): 456-464 (1981)

share|improve this answer
    
related "A 2010 Algorithm for the Knapsack Problem" rjlipton.wordpress.com/2010/02/05/… –  J.F. Sebastian Jun 4 '10 at 17:56
add comment

Here's @MicSim's comment to @sdcvvc's answer implemented in Python:

def abcd(nums):
    sums = dict((a+b, (a,b)) for a, b in combinations(nums, 2))

    for c, d in combinations(sorted(nums), 2): # c < d
        if (d-c) in sums:
            a, b = sums[d-c]
            assert (a+b+c) == d
            if a == c or b == c: continue # all a,b,c,d must be different
            a,b,c = sorted((a,b,c))
            assert a < b < c < d
            return a,b,c,d

Where combinations() could be itertools.combinations() or

def combinations(arr, r):
    assert r == 2 # generate all unordered pairs
    for i, v in enumerate(arr):
        for j in xrange(i+1, len(arr)):
            yield v, arr[j]

It is O(N2) in time and space.

Example:

>>> abcd(range(1, 10000))
(1, 2, 3, 6)
share|improve this answer
    
Prove it :) :) :) –  Hamish Grubijan Jun 6 '10 at 3:58
2  
@Hamish Grubijan: combinations() produces N*(N-1)/2 pairs therefore sums takes O(N**2) memory and O(N**2) time to create it, and there are O(N**2) (c,d) pairs to process. (d-c) in sums is assumed to be O(1) therefore the whole (c,d)-loop is O(N**2) in time. –  J.F. Sebastian Jun 9 '10 at 10:48
add comment

Your Answer

 
discard

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.