# How to optimize this suboptimal Set-Cover solution?

I wrote this program to test how long it would take to "solve" the set-cover problem.

``````using System;
using System.Collections.Generic;
using System.Linq;
using System.Text;
using System.Diagnostics;
using MoreLinq;

namespace SetCover
{
class Program
{
const int maxNumItems = 10000;
const int numSets = 5000;
const int maxItemsPerSet = 300;

static void Main(string[] args)
{
var rand = new Random();
var sets = new List<HashSet<int>>(numSets);
var cover = new List<HashSet<int>>(numSets);
var universe = new HashSet<int>();
HashSet<int> remaining;
var watch = new Stopwatch();

Console.Write("Generating sets...");
for (int i = 0; i < numSets; ++i)
{
int numItemsInSet = rand.Next(1, maxItemsPerSet);

for (int j = 0; j < numItemsInSet; ++j)
{
}
}
Console.WriteLine("Done!");

Console.Write("Computing universe...");
foreach (var set in sets)
foreach (var item in set)
Console.WriteLine("Found {0} items.", universe.Count);

watch.Start();

//Console.Write("Removing subsets...");
//int numSetsRemoved = sets.RemoveAll(subset => sets.Any(superset => subset != superset && subset.IsSubsetOf(superset)));
//Console.WriteLine("Removed {0} subsets.", numSetsRemoved);

//Console.Write("Sorting sets...");
//sets = sets.OrderByDescending(s => s.Count).ToList();
//Console.WriteLine("{0} elements in largest set.", sets[0].Count);

Console.WriteLine("Computing cover...");
remaining = universe.ToHashSet();
while (remaining.Any())
{
Console.Write("  Finding set {0}...", cover.Count + 1);
var nextSet = sets.MaxBy(s => s.Intersect(remaining).Count());
remaining.ExceptWith(nextSet);
Console.WriteLine("{0} elements remaining.", remaining.Count);
}
Console.WriteLine("{0} sets in cover.", cover.Count);

watch.Stop();

Console.WriteLine("Computed cover in {0} seconds.", watch.Elapsed.TotalSeconds);

}
}

public static class Extensions
{
public static HashSet<TValue> Clone<TValue>(this HashSet<TValue> set)
{
var tmp = new TValue[set.Count];
set.CopyTo(tmp, 0);
return new HashSet<TValue>(tmp);
}

public static HashSet<TSource> ToHashSet<TSource>(this IEnumerable<TSource> source)
{
return new HashSet<TSource>(source);
}
}
}
``````

This is just a greedy sub-optimal solution, but it still took 147 seconds to run. I think however, that this solution should be pretty close to optimal, so it should be good enough for my purposes. How can I speed it up though?

I commented out a few lines because they do more harm than good. Edit: Computing the universe should actually not be apart of the timing... that can be known beforehand.

-
If you want serious time measurements, better remove the WriteLine() statements. –  Henk Holterman Oct 9 '10 at 22:02
@Henk: Not too concerned about "serious" measurements. The specific number doesn't really matter, just that it gets lower ;) –  Mark Oct 9 '10 at 22:22

I haven't gone deeply into the detail of your code/algorithm, but I'm gonna use some theory to advice you. As henk commented, in order to perform a "good" benchmark you MUST remove all unneeded code and run your program in Release mode with full optimization and from commandline.

Then, remember that you are running managed code: C# (and Java) are designed for interoperability, not for performance, while they are still both good platforms. You should try either to reimplement your code in C++ if you need performance, or, if you wish, try to use Mono with AOT (ahead-of-time compiler): it bursts performance a lot

`````` mono --aot=full YourProgram.exe
``````

Now more about benchmarks and optimality: have you compared your results with others? Did you run other set-cover algorithms on your same hardware, or can you compare your hardware to others that ran the same algorithm?

And... how close is your solution to optimal? Can you provide [yourself] an estimate? The key is in LINQ, which I hate because you lose control of your code for simplicity of code. What's the complexity of a LINQ? If each LINQ is O(n), your algorithm is O(n^3) but I might suggest you to replace

``````remaining.Any()
``````

with

``````remaining.Count > 0
``````

to gain a magnitude of complexity.

Mine are just advices, hope to have been of help

-
`remaining.Any()` only runs 15 times with 1250 elements... I don't think it's a bottleneck, and I'd suspect it's `O(1)` anyway, no? Your suggestions are good though, didn't know about that mono thing. I don't know of any other C# implementations of set-cover or I'd be using them. Porting it to C++ or something is not a problem, but I need to get the theory behind the algo right first. By "optimal" I mean "produces the fewest number of sets", not as in terms of efficiency. I don't know what the optimal sol'n is, because it's NP-complete and would take too darn long to solve. –  Mark Oct 10 '10 at 0:37
I'm pretty sure the most expensive line is `sets.MaxBy(s => s.Intersect(remaining).Count())` because it has to compute the intersection of 2 sets about 5000 times. I'm not sure exactly how costly the `Intersect` method is... at least `O(n log n)` I think. –  Mark Oct 10 '10 at 0:43
Yea, I read the code of Any() and actually it's O(1). I also found on Wikipedia that the greedy algorithm works usually good, being polynomial, so I would now focus on the runtime environment :) –  djechelon Oct 10 '10 at 0:46
Someday :) I've got a million ideas floating around in my head... every now and then I like to tackle what I think will the biggest hurdle w/out actually completing the project... I'm hoping that if I just solve all the tricky stuff beforehand, it'll be smooth sailing... –  Mark Oct 12 '10 at 8:33