# Optimizing or improving my dynamic programming algorithm

I have a set of unit tests T which are used in the weekly regression and a set of values V used for coverage analysis.

The logging database maps a test ti to the set of values vi (vi is a proper subset of V) it hits (i.e., whatever the test covers).

Also, N(T) >> N(V) i.e, the number of tests is much greater than the number of values

Problem: I'd like to find the smallest subset of T, Ts, which covers all the values in V.

This gives the smallest and best sample of tests to at least cover all of V. Of course, I'm interested in adding permutations of V, but that's for later.

I could formulate this as a standard dynamic programming problem:

If Tm represents the set of tests t1 through tm (and)

if Vn represents the set of values v1 through vn (and)

P(Tm, Vn) represents the minimum required number of tests in Tm to hit all values in Vn,

P(Tm, Vn) = min(

``````               {for 0 < i < m   min ( P(Tm-1, Vn - V(tm) ) } + 1,  // include test tm
P(Tm-1, Vn) // exclude test tm

)
``````

P(Tnull, Vn) = N(T) + 1 // some high value that can't be reached

P(Tm, Vnull) = 0 // all values have been hit!

This leaves me with a ton of small problems to solve (and then i can use memoization and all that good stuff).

But, I can't help but think that this should reduce to a standard graph problem. Since my memory of graph problems is almost non-existent, I glanced through wiki to see if I could see a similar problem. But alas, my eyes couldn't catch any.

My questions are:

i) is there a standard graph reduction for this?

ii) any good optimizations i can do to speed up the solution?

Edits: Just found out that this problem is a Set Cover problem.

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