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 came up with the following implementation for the Greedy Set Cover after much discussion regarding my original question here. From the help I received, I encoded the problem into a "Greedy Set Cover" and after receiving some more help here, I came up with the following implementation. I am thankful to everyone for helping me out with this. The following implementation works fine but I want to make it scalable/faster.

By scalable/faster, I mean to say that:

  • My dataset contains about 50K-100K sets in S
  • The number of elements in U itself is very small in the order of 100-500
  • The size of each set in S could be anywhere from 0 to 40

And here goes my attempt:

U = set([1,2,3,4])
R = U
S = [set([1,2]), 
     set([1]), 
     set([1,2,3]), 
     set([1]), 
     set([3,4]), 
     set([4]), 
     set([1,2]), 
     set([3,4]), 
     set([1,2,3,4])]
w = [1, 1, 2, 2, 2, 3, 3, 4, 4]

C = []
costs = []

def findMin(S, R):
    minCost = 99999.0
    minElement = -1
    for i, s in enumerate(S):
        try:
            cost = w[i]/(len(s.intersection(R)))
            if cost < minCost:
                minCost = cost
                minElement = i
        except:
            # Division by zero, ignore
            pass
    return S[minElement], w[minElement]

while len(R) != 0:
    S_i, cost = findMin(S, R)
    C.append(S_i)
    R = R.difference(S_i)
    costs.append(cost)

print "Cover: ", C
print "Total Cost: ", sum(costs), costs

I am not an expert in Python but any Python-specific optimizations to this code would be really nice.

share|improve this question

2 Answers 2

up vote 2 down vote accepted

What sorts of times are you getting vs what you need? Surely most of the execution time is spent in c-level code finding set intersections, so there's not much optimization you can do? With some random data (results may vary with your data of course, not sure if these are good values) of 100000 sets, 40 elements in each set, 500 unique elements, weights random from 1 to 10,

print 'generating test data'    
num_sets = 100000
set_size = 40
elements = range(500)
U = set(elements)
R = U
S = []
for i in range(num_sets):
    random.shuffle(elements)
    S.append(set(elements[:set_size]))
w = [random.randint(1,100) for i in xrange(100)]

C = []
costs = []

I got performance like this with cProfile:

         8200209 function calls in 14.391 CPU seconds

   Ordered by: standard name

   ncalls  tottime  percall  cumtime  percall filename:lineno(function)
        1    0.000    0.000   14.391   14.391 <string>:1(<module>)
       41    4.802    0.117   14.389    0.351 test.py:23(findMin)
        1    0.001    0.001   14.391   14.391 test.py:40(func)
  4100042    0.428    0.000    0.428    0.000 {len}
       82    0.000    0.000    0.000    0.000 {method 'append' of 'list' objects}
       41    0.001    0.000    0.001    0.000 {method 'difference' of 'set' objects}
        1    0.000    0.000    0.000    0.000 {method 'disable' of '_lsprof.Profiler' objects}
  4100000    9.160    0.000    9.160    0.000 {method 'intersection' of 'set' objects}

Hm, so mostly apparently 1/3 of the time isn't in set intersections. But I personally wouldn't optimize any more, especially at the cost of clarity. There's not going to be much you can do with the other 2/3, so why bother?

share|improve this answer
    
+1 Thank you. You are right. I was looking for unnecessary optimizations. In my case, it was running in about 15 seconds which is good for me. Thank you once again. –  Legend Oct 31 '11 at 9:14

I use a trick when I implemented the famous greedy algorithm for set cover (no weights) in Matlab. It is possible that you could extend this trick to the weighted case somehow, using set cardinality / set weight instead of set cardinality. Moreover, if you use NumPy library, exporting Matlab code to Python should be very easy.

Here is the trick:

  1. (optional) I sorted the sets in descending order with respect to the cardinality (i.e. number of elements they contain). I also stored their cardinalities.
  2. I select a set S, in my implementation it is the largest (i.e. first set of the list), and I count how many uncovered elements it contains. Let's say that it contains n uncovered elements.
  3. Since now I know there is a set S with n uncovered elements, I don't need to process all the sets with cardinality lower than n elements, because they cannot be better than S. So I just need to search for the optimal set among the sets with cardinality at least n; with my sorting, we can focus on them easily.
share|improve this answer

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.