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I have a collection of std::set. I want to find the intersection of all the sets in this collection, in the fastest manner. The number of sets in the collection is typically very small (~5-10), and the number of elements in each set is is usually less than 1000, but can occasionally go upto around 10000. But I need to do these intersections tens of thousands of time, as fast as possible. I tried to benchmark a few methods as follows:

  1. In-place intersection in a std::set object which initially copies the first set. Then for subsequent sets, it iterates over all element of itself and the ith set of the collection, and removes items from itself as needed.
  2. Using std::set_intersection into a temporary std::set, swap contents to a current set, then again find intersection of the current set with the next set and insert into the temp set, and so on.
  3. Manually iterate over all the elements of all sets like in 1), but using a vector as the destination container instead of std::set.
  4. Same as in 4, but using a std::list instead of a vector, suspecting a list will provide faster deletions from the middle.
  5. Using hash sets (std::unordered_set) and checking for all items in all sets.

As it turned out, using a vector is marginally faster when the number of elements in each set is small, and list is marginally faster for larger sets. In-place using set is a substantially slower than both, followed by set_intersection and hash sets. Is there a faster algorithm/datastructure/tricks to achieve this? I can post code snippets if required. Thanks!

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2  
The question really depends on whether or not you are expected to find many common elements or not, as this alters the "best" structure that one can come up with. For example, a 6th method could be to simply use and std::unordered_map and count the number of occurrences of each elements. It's O(N) in the total number of elements. Then, you just pick the elements that have a total equal to the number of sets, O(M) in the number of distinct elements. No idea how well it would perform. –  Matthieu M. Oct 13 '12 at 19:21
    
@MatthieuM. I see. I will give this a try, though I suspect, it won't be faster than a std::list due to hashing and other overheads. Thanks! –  Paresh Oct 13 '12 at 19:43
    
@MatthieuM. This method will give the resulting set in unsorted order. Luckily, I have two use cases, one which requires the result in sorted order, and one which does not. If this method is reasonably fast, I can use it atleast for the case where the intersection is not needed to be sorted. –  Paresh Oct 13 '12 at 20:25
    
@MatthieuM. I tried this approach, and for my data, this was only slightly faster than my approach 5 (using unordered_set). –  Paresh Oct 13 '12 at 21:02
3  
You could try this idea. Worst case linear (can't avoid that, if the sets have mostly the same elements), but if the intersection is small, it can be much faster. –  Daniel Fischer Oct 14 '12 at 2:43

3 Answers 3

up vote 5 down vote accepted

You might want to try a generalization of std::set_intersection(): the algorithm is to use iterators for all sets:

  1. If any iterator has reached the end() of its corresponding set, you are done. Thus, it can be assumed that all iterators are valid.
  2. Take the first iterator's value as the next candidate value x.
  3. Move through the list of iterators and std::find_if() the first element at least as big as x.
  4. If the value is bigger than x make it the new candidate value and search again in the sequence of iterators.
  5. If all iterators are on value x you found an element of the intersection: Record it, increment all iterators, start over.
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I would not recommend std::find_if when one is working with std::set, after all, std::set features both std::lower_bound and std::upper_bound with are typically faster. –  Matthieu M. Oct 13 '12 at 19:23
1  
@MatthieuM. not in this case, find_if will on average never need to advance more than two elements and is thus O (1), while ???er_bound is O (log n). –  leftaroundabout Oct 13 '12 at 19:30
    
@MatthieuM.: Obviously, it depends on the interface of the algorithm and I would operate on a sequence of pairs of input iterators: std::set_intersection() does as well. Interestingly, I think the complexity of your suggested approach is O((n log n) * m) : wheren is the maximum size of the sets and m is the number of sets. My algorithm has complexity O(n * m). I think my approach wins. –  Dietmar Kühl Oct 13 '12 at 19:30
    
@leftaroundabout Thanks! I did not understand why find_if will on average never need to advance more than two elements? –  Paresh Oct 13 '12 at 19:37
    
@leftaroundabout: like Paresh I wonder where the 2 elements come from (I might be missing something obvious). It seems to me it would depend on how the data is distributed, would it not ? For example suppose than I have a set of 100 elements and another of 1000 elements covering the same range. Then in average I will need to skip about 10 elements from the large set at each step. –  Matthieu M. Oct 13 '12 at 19:51

Night is a good adviser and I think I may have an idea ;)

  • Memory is much slower than CPU these days, if all data fits in the L1 cache no big deal, but it easily spills over to L2 or L3: 5 sets of 1000 elements is already 5000 elements, meaning 5000 nodes, and a set node contains at least 3 pointers + the object (ie, at least 16 bytes on a 32 bits machine and 32 bytes on a 64 bits machine) => that's at least 80k memory and the recent CPUs only have 32k for the L1D so we are already spilling into L2
  • The previous fact is compounded by the problem that sets nodes are probably scattered around memory, and not tightly packed together, meaning that part of the cache line is filled with completely unrelated stuff. This could be alleviated by provided an allocator that keeps nodes close to each others.
  • And this is further compounded by the fact that CPUs are much better at sequential reads (where they can prefetch memory before you need it, so you don't wait for it) rather than random reads (and a tree structure unfortunately leads to quite random reads)

This is why where speeds matter, a vector (or perhaps a deque) are so great structures: they play very well with memory. As such, I would definitely recommend using vector as our intermediary structures; although care need be taken to only ever insert/delete from an extremity to avoid relocation.

So I thought about a rather simple approach:

#include <cassert>

#include <algorithm>
#include <set>
#include <vector>

// Do not call this method if you have a single set...
// And the pointers better not be null either!
std::vector<int> intersect(std::vector< std::set<int> const* > const& sets) {
    for (auto s: sets) { assert(s && "I said no null pointer"); }

    std::vector<int> result; // only return this one, for NRVO to kick in

    // 0. Check obvious cases
    if (sets.empty()) { return result; }

    if (sets.size() == 1) {
        result.assign(sets.front()->begin(), sets.front()->end());
        return result;
    }


    // 1. Merge first two sets in the result
    std::set_intersection(sets[0]->begin(), sets[0]->end(),
                          sets[1]->begin(), sets[1]->end(),
                          std::back_inserter(result));

    if (sets.size() == 2) { return result; }


    // 2. Merge consecutive sets with result into buffer, then swap them around
    //    so that the "result" is always in result at the end of the loop.

    std::vector<int> buffer; // outside the loop so that we reuse its memory

    for (size_t i = 2; i < sets.size(); ++i) {
        buffer.clear();

        std::set_intersection(result.begin(), result.end(),
                              sets[i]->begin(), sets[i]->end(),
                              std::back_inserter(buffer));

        swap(result, buffer);
    }

    return result;
}

It seems correct, I cannot guarantee its speed though, obviously.

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Thanks! The compactness of memory was the reason I tried the option 3 in the original question: using a vector as an intermediate container, just as you have done. The difference being you used the set_intersection, which requires two vectors, while I kept 1 vector, with the disadvantage that I had to erase from the middle. Even though your approach should ideally have been faster, I guess the complex factors like contiguous memory, caching (1 array vs 2) etc are making this slower than the options 3 and 4 that I tried above. Of course, mileage may vary based on the data. –  Paresh Oct 14 '12 at 15:59
    
+1 for thinking in terms of memory and caching, and giving a nice explanation! As a side note, I am considering using vectors instead of std::set, and inserting in sorted order into vectors if that is comparable. Compactness may make it reasonably fast, and intersections would definitely be faster. –  Paresh Oct 14 '12 at 16:01

The main problem in every of your algorithms is the remove operation. On std::vector it is way to expensive, std::list works much better, but on the other hand the access of elements has linear complexity.

However, if M = M1 + M2 + ... + Ms is the number of elements in each set (1..s) and the sets are bounded in a given range R = #[R1...R2] you could use the following (M + R) approach:

  1. Create a std::vector V with size R and initialize it with zero ( O(R) )
  2. For each set S iterate through S and increment the according value in V ( O(MS) per set = O(M))
  3. Iterate through V, only the elements which number equals the number of sets are included in every set (again O(R))

However, if the number of elements isn't clear or the elements can't be identified with a simple integer then this bucket-approach isn't suitable for you.

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Thanks! However, the number of elements is not well-defined. Also, the possible values are generally much larger, that is, R >> M. This will tend to be quite slow I suspect. Also, if it had been possible, I think a bit array for each set would be a better option. Bit array for each, with a 1 if that element occurs in that set, and so on. Then bitwise and all of them (bitset will typically be a array of integers, so this will be quite fast). In any case, this method cannot be applied here. Thanks though! –  Paresh Oct 13 '12 at 19:34
    
@Paresh: If R >> M then this will be definitely to slow. And if the number isn't well-defined this approach will be useless. In this case Dietmar is on the right track. –  Zeta Oct 13 '12 at 19:40

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