# Given a vector of maximum 10 000 natural and distinct numbers, find 4 numbers(a, b, c, d) such that a + b + c = d

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)

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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`. –  Arrieta 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
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## 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.

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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
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
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
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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)

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related "A 2010 Algorithm for the Knapsack Problem" rjlipton.wordpress.com/2010/02/05/… –  J.F. Sebastian Jun 4 '10 at 17:56
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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)
``````
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Prove it :) :) :) –  Hamish Grubijan Jun 6 '10 at 3:58
@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
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