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Given a string S, I want to find out whether there are non-overlapping substrings A, B and C in S, so that the equation A + B = C holds when the substrings are interpreted as decimal numbers.

Example: For S = 17512, the answer is yes, because 12 + 5 = 17 holds.

This is not a homework question, I have tried approaching this problem building a suffix array






but then I realize that given 132, 1 + 2 = 3 Would require other forms of permutations in selection?

How do you solve this in an efficient way?

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Could you also have 1 + 7 = 5 + 1 + 2? – j.con Mar 17 '14 at 19:41
do all digits have to be in the equation? Also, 12 is not a digit. Can you form numbers taking any digits in any order? – Luchian Grigore Mar 17 '14 at 19:42
Yes 12 is not a digit , Multiple digits can be taken as well as long as a substring sums up with another substring to a substring in the result. i will edit the question – ashok v Mar 17 '14 at 19:43
Looks what you need is more like an AST, than reducing to the 'digits' ... – πάντα ῥεῖ Mar 17 '14 at 19:46
What about overlapping substrings? is 1+1=2 a valid equation for "12"? is 23+34=57 a valid equation for "23457"? Must all characters be used? is 1+2=3 a valid equation for "1234"? – Kevin Mar 17 '14 at 19:48
up vote 2 down vote accepted

Let S be the decimal representation of the number. If n = |S| is small enough (<500 or so), you can use the following algorithm:

Let us enumerate A and C from the equation A + B = C (where we assume w.l.o.g. A > B). We know that they need to be of around the same size (plus/minus one digit), so enumerating the possibilities is a cubic operation (there are O(n3) candidates).

For every candidate pair (A, C), we need to check whether B = C - A is in the string and not overlapping with any of the A or C substrings. We can compute the difference in linear time using arithmetics in base 10.

The tricky part is to check whether B is a substring not overlapping A or C. A and C split the string into 3 parts:

S = xAyCz

If we enumerate them in a clever way, with fixed start positions and decreasing size, we can maintain suffix automata of part x and the reverses of parts y and z.

Now we can check in linear time whether B = C - A (or its reverse) exists in one of the three parts.

Time complexity of this approach: Θ(n4).

There is a variation of this which is slightly more complicated, but faster (thanks to Evgeny for pointing it out):

  • Create a suffix tree of the input string. Every node represents a substring. Store in every node a balanced binary search tree of the positions where the substring occurs in the string. You might need persistent trees here to save time and space.
  • Enumerate A and C, but this time starting from the least-significant digit (the rightmost end).
  • While growing A and C from right to left, keep track of the result of B = C - A. It will also grow from least-significant to most-siginificant digit. Do a search for B in the suffix tree. You can do this one digit at a time, so you can make grow A and C by 1 digit, update B and locate it in the suffix tree in O(1).
  • If B is positive, do three range queries in the BBST of positions to check whether B occurs in the string and does not overlap A or C

Runtime: O(n3 log n).

UPDATE: regarding the simplified version where all characters need to be used:

We first realize that we can do arithmetics on substrings of our string in linear time, if we work in base 10.

Now we want to find the splitting points a < b, so that your three substrings are A =, B = and C =

We can prove that there is only a constant number of candidates for a and b, because all three parts must have approximately the same size for the equation to hold.

Using arbitrary precision arithmetics, we can easily try out all candidate pairs (a,b) and for each of those, find M = max(A,B,C). Then just check whether M is the sum of the other two numbers.

Total time complexity: Θ(n).

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This assumes all digits are used, which I don't think is part of the assumptions of the problem. It also assumes digits are used in contiguous subsets, which may or not be part of the assumptions of the problem. – user2566092 Mar 17 '14 at 20:29
@user2566092: Substring to me means "contiguous". – Niklas B. Mar 17 '14 at 20:31
still you assume that all digits are used, which might not be what the OP intended. – user2566092 Mar 17 '14 at 20:33
@user2566092 quote from a comment: "All characters need not be used" – Niklas B. Mar 17 '14 at 20:33
ok so we're in agreement, OP doesn't need all characters to be used but your solution assumes that all characters are used. – user2566092 Mar 17 '14 at 20:34

If you are allowed to form substrings from arbtirary subsets of digits in their original given order as long as your digits don't overlap in the 2 summands and the sum, then I believe your problem is NP-complete. I think this is even true if the target sum is given and all you have to do is find two non-overlapping substrings of digits that add up to the target sum. However I don't have a proof of NP-completeness yet.

If your substrings of digits have to be consecutive then the situation is much better. You can search over all combinations of 2 summands and 1 sum for the starting and ending points of the numbers in O(n^6) time, and certainly there are improvements that can be made because e.g. for a given target sum, you only need to search over pairs of substrings whose max length adds up to the length of your target sum either exactly or minus 1.

UPDATE: If you need to find 3 non-overlapping contiguous substrings that give you the summation formula, then you can hash all O(n^2) substring values and then hash the sum of all pairs of summands to see if the target sum is in your hash table. If so, then you only need to check if the summand beginning and ending indices do not overlap the summand indices. Worst-case time is O(n^6), expected running time is O(n^5) for random inputs.

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@NiklasB. I'm assuming constant time arithmetic and hashing, which may not be a valid assumption. Updated accordingly. – user2566092 Mar 17 '14 at 21:16
good answer to the Simpler case infact ! – ashok v Mar 17 '14 at 21:17

Assuming (As in both your examples) that your 3 substrings are contiguous, non-overlapping, non-negative, and between them cover the whole input, then there is a quadratic time solution.

  • First (temporarily) assume the order is aaabbbccc where aaa+bbb=ccc, and aaa>bbb.
  • The length of ccc must either be the same as aaa or at most one larger.
  • So the length of aaa (len_a) must be between n/3 and n/2.
  • Given the len_a, there are two choices for len_c --- len_a or len_a+1.
  • Given these, there is only one possible length of bbb. len_b = n-len_a = len_c
  • Test these 2(n/2 - n/3) = n/3 cases.
  • Each test is O(n) cost due to string to int conversion.

Repeat the above analysis for two permutations (aaa>bbb v bbb>=aaa), times three permutations (aaa+bbb=ccc v aaa+ccc=bbb v bbb+ccc=aaa)

You could improve the test to check only the most (or least) significant i digits of the three numbers, returning early if the sum was not possible. Assuming randomly distributed digits, you might be able to show that the expected run time of such a test was constant. This would turn the whole algorithm into an O(n) runtime.

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"between them cover the whole input" is unfortunately not the case. I also thought that at first :( – Niklas B. Mar 17 '14 at 20:50
Also you assume constant-time arithmetics, but that is unlikely to be available when the string is beyond the word size – Niklas B. Mar 17 '14 at 20:54
I don't assume constant time arithmetic. I assume O(n) cost of testing each equality case. This covers both string to int conversion and arithmetic costs. In any case I probably wouldn't convert to an int representation, but do the maths in the string domain. In the case of amortised constant test option, I believe the arithmetic costs grow the same as the string to int conversion costs i.e. amortised constant. – Ian Mar 19 '14 at 9:22

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