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You are given n numbers and you have to find the number of pairs such that at least one digit is common in between them.

Eg. For 5 numbers :

2837 2818 654 35 931

Answer : 6

The pairs here are (2837,2818), (2837,35), (2837,931), (2818,931), (654,35), (35,931)

My Attempt : I took a structure which stores the number in decimal, the number in form of its digits in array and number of digits in that number.

Now for each number I hashed that number in array conatining index 0-9 and the checked with all following numbers wether any of their digit is already present.

My attempt is O(n^2), which is slow. Is there another algorithm that will work faster?

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You hashed a value, but failed to use a hashtable lookup? –  leppie Jul 16 '12 at 6:37
My solution was working correctly but taking quite a lot time when n was large –  L.ppt Jul 16 '12 at 6:39
This cannot be done faster than O(n^2) because you need that O(n^2) at least to generate the answer in the worst case. –  Grigor Gevorgyan Jul 16 '12 at 7:15
@GrigorGevorgyan - I assume that the answer for the example in the question is intended to be simply 6. You don't have to list all the pairs. –  Jirka Hanika Jul 16 '12 at 7:42
@JirkaHanika Yes you are correct pairs were shown for more and clear explaintion, only count is requred as answer and even in question its boldly written as "number of pairs". –  L.ppt Jul 16 '12 at 7:53

3 Answers 3

create a an array of sets, one for each digit.

iterate your numbers and put each number in each set for the digits it contains.

iterate of all 10 sets and combine every element of a set with all other elements in the same set. (or all other elements larger than itself, if you don't want (a,b) and (b,a) in your result.

I think this is still O(n^2) but it could be paralized nicely using a fork join approach.


Just realized you only want the number of results. So that would be the sum of size * size-1 for all sets. Since inserting into a set and getting its size should be linear (I think) this might actually be O(n)


If your numbers a distinct and you are only interested in the number of pairs, you don't even need sets, you just need a counter instead.

doesn't work From the comments:

Consider 1st pair in above questions test case (2837,2818), this will put first number in set containing digit 2 and 8 and same for 2818 now they are to be counted as one but counting in 2 and 8 will count it twice. I hope you understand what I am trying to say...

So this approach doesn't work ... I guess it might be of value as a warning for others.

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Enumerating the pairs, rather than just computing the number of them, necessarily takes Ω(n²) time in the worst case, since there are O(n²) of them. –  larsmans Jul 16 '12 at 6:58
@larsmans you are right, I just realized only the number of pairs is needed. Edited the answer. –  Jens Schauder Jul 16 '12 at 7:13
@L.ppt what do you mean by digit can be very big? Do you mean n can be very big? Or do you mean each number can be very big? If n can be up to 10^18 you have a problem I think. –  Jens Schauder Jul 16 '12 at 7:16
@L.ppt: What decimal digit (not a number!) is bigger than 9? –  fork0 Jul 16 '12 at 7:16
sorry that was number not digit, apology for that comment.... –  L.ppt Jul 16 '12 at 7:19

It is crucial to realize what are variables and what are constants here.

Number of digits is a constant (10). So is the number of all sets of digits (1024). So is the number of all pairs of such sets (220). Let's take advantage of that.

Create an array of 1024 integers, each bucket (index) corresponding to a set of digits; store the number of input numbers that have exactly that set of digits in each bucket.

For example, 3606 has digits 0, 3, and 6, and so it would be counted in bucket 20 + 23 + 26 = 73.

Compare each buckets with each other bucket (but not itself). Whenever the two indexes share a digit (this can be determined using the & operator), multiply the content of those two buckets together, and add the product to a globally maintained sum.

Compare each bucket also to itself, and add only x * (x - 1) / 2 to the globally maintained sum, where x is the content of the bucket.

That sum is your result.

Worst case: O(n) where n is input size.

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I think in this form it has the same problem as my proposed solution, but this one might be fixable. –  Jens Schauder Jul 16 '12 at 8:02
Sorry, I'm wrong. I thought you double count pairs that have more than one digit in common, but you don't. –  Jens Schauder Jul 16 '12 at 8:09
could you please explain why did you use this method of 2^0 + 2^3 + 2^6 for mapping.I am more interested in knowing how did you came up with it. –  gabber12 Dec 24 '12 at 17:23
Any fixed mapping would do, as long as it never maps two different sets of digits to the same code. I chose this one for space efficiency, cache-friendliness, and for ease of the nested iteration at the end: with this particular mapping, there are no "holes" in the array (no non-codes between valid codes). Last but not least, this coding requires only a handful of machine instructions per character of input on any normal architecture. No exponentiation operation is needed, because for any x, 2^x = 1 shift-to-left x. –  Jirka Hanika Dec 25 '12 at 21:13

First of all, I notice that the position of common digits does not matter.

In that case, I sketch a little algorithm with hash table: form 10 bins, one for each digit. Then, for each number, put (uniquely) the ID of the number in each bin corresponding to each digit it has. This operation is O(n*k), k is the number of digits of numbers. Finally, to form all pairs, take pairs of numbers inside each bin. To remove possibly doublons, arrange each pairs (a,b) with a

I think the worst case is in fact O(n^2); in fact, I do think that this step must have a complexity of O(n^2) as you want to take all pairs (at max n*(n+1)/2). So the final complexity is really quadratic.

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