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.

Given a universe of elements U = {1, 2, 3,...,n} and a number of sets in this universe {S1, S2,...,Sm}, what is the smallest set we can create that will cover at least one element in each of the m sets?

For example, given the following elements U = {1,2,3,4} and sets S = {{4,3,1},{3,1},{4}}, the following sets will cover at least one element from each set: {1,4} or {3,4} so the minimum sized set required here is 2.

Any thoughts on how this can be scaled up to solve the problem for m=100 or m=1000 sets? Or thoughts on how to code this up in R or C++?

The sample data, from above, using R's library(sets).

s1 <- set(4, 3, 1)
s2 <- set(3, 1)
s3 <- set(4)
s <- set(s1, s2, s3)

Cheers

share|improve this question
1  
Did you mean n=4 and m=100? Since per your definition, m is the number of sets, n is the number of elements! –  Tommy Jul 19 '11 at 17:22
    
well spotted @Tommy. thanks –  jedfrancis Jul 19 '11 at 17:32

4 Answers 4

This is the hitting set problem, which is basically set cover with the roles of elements and sets interchanged. Letting A = {4, 3, 1} and B = {3, 1} and C = {4}, the element-set containment relation is

  A B C
1 + + -
2 - - -
3 + + -
4 + - +

so you basically want to solve the problem of covering {A, B, C} with sets 1 = {A, B} and 2 = {} and 3 = {A, B} and 4 = {A, C}.

Probably the easiest way to solve nontrivial instances of set cover in practice is to find an integer programming package with an interface to R or C++. Your example would be rendered as the following integer program, in LP format.

Minimize
    obj: x1 + x2 + x3 + x4
Subject To
    A: x1 + x3 + x4 >= 1
    B: x1 + x3 >= 1
    C: x4 >= 1
Binary
    x1 x2 x3 x4
End
share|improve this answer
    
hi @bar, this looks great. Trouble is (and I'm coming out of the closet here) I'm not familiar with LP! Seem like I have some weekend reading to do! :-) –  jedfrancis Jul 23 '11 at 8:32

If you restrict each set to have 2 elements, you have the np-complete problem node cover. I would guess the more general problem would also be NP complete (for the exact version).

share|improve this answer
    
hi, the elements in each set are important in the specific problem I'm solving so cannot be reduced to 2 elements. –  jedfrancis Jul 19 '11 at 16:55
    
Sure it is. If the 2-set version is NP-complete, it is NP-hard too. Since you can trivially solve instances of the 2-set version with the N-set version (use the N-set version with N=2), it is NP-hard as well. Since you can easily verify a certificate in polynomial time (check the intersection with each set in S), it is also in NP. Hence NP-complete. –  Patrick87 Jul 19 '11 at 16:57

If you're just interested in an algorithm (rather than an efficient/feasible algorithm), you can simply generate subsets of the universe of increasing cardinality and check that the intersection with all the sets in S is non-empty. Stop as soon as you get one that works; the cardinality is the minimum possible.

The complexity of this is 2^|U| in the worst case, I think. Given Foo Bah's answer, I don't think you're going to get a polynomial-time answer...

share|improve this answer
    
I'll give this a try, but ideally I'm looking for a feasible and efficient algorithm that can scale to a very large number of sets with a large number of elements in each set. –  jedfrancis Jul 19 '11 at 17:26

At first I misunderstood the complexity of the problem and came up with a function that finds a set that covers the m sets - but I then realized that it isn't necessarily the smallest one:

cover <- function(sets, elements = NULL) {
  if (is.null(elements)) {
    # Build the union of all sets
    su <- integer() 
    for(si in sets) su <- union(su, si)
  } else {
    su <- elements
  }

  s <- su
  for(i in seq_along(s)) {
    # create set candidate with one element removed
    sc <- s[-i] 

    ok <- TRUE
    for(si in sets) {
      if (!any(match(si, sc, nomatch=0L))) {
        ok <- FALSE
        break
      }
    }

    if (ok) {
      s <- sc
    }
  }

  # The resulting set
  s
}

sets <- list(s1=c(1,3,4), s2=c(1,3), s3=c(4))
> cover(sets) # [1] 3 4

Then we can time it:

n <- 100  # number of elements
m <- 1000 # number of sets
sets <- lapply(seq_len(m), function(i) sample.int(n, runif(1, 1, n)))
system.time( s <- cover(sets) ) # 0.53 seconds

Not too bad, but still not the smallest one.

The obvious solution: generate all permutations of elements and pass is to the cover function and keep the smallest result. This will take close to "forever".

Another approach is to generate a limited number of random permutations - this way you get an approximation of the smallest set.

ns <- 10 # number of samples
elements <- seq_len(n)
smin <- sets
for(i in seq_len(ns)) {
   s <- cover(sets, sample(elements))
   if (length(s) < length(smin)) {
     smin <- s
   }
}
length(smin) # approximate smallest length 
share|improve this answer
    
thanks for this reply, it provides a good basis for starting to coding up a solution. –  jedfrancis Jul 23 '11 at 8:28

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.