I'm working on an open-source approximation algorithms library for graphs and networks using some popular python packages as a base. The main goal is to encompass up-to-date approximation algorithms for NP-Complete problems over graphs and networks. The reason for this is 1) I haven't seen a nice (modern) consolidated package that covers this and 2) it would be a nice pedagogical tool for learning about approximation algorithms on NP-Hard optimization problems.

In building this library I am using unit-tests to sanity check (as any proper developer would). I am somewhat cautious about my unit tests in that by their very nature, approximation algorithms may not return the correct solution. Currently I am solving some small instances by hand and then assuring that the returned result matches that, but this is not desirable, nor scalable in an implementation sense.

What would be the best way to unit test approximation algorithms? Generate random instances and ensure that the returned results are less than the bound guaranteed by the algorithm? That would seem to have false positives (the test just got lucky that time, not guaranteed for all instances to be below bound).

random. – Ray Toal Sep 12 '11 at 17:04pqis hard, unless you already knowpandqbecause you generated them. Can a similar principle be applied to your graph/network problems? – Tom Zych Sep 12 '11 at 17:10