TSP might not be a very good description of this question. The reason being your not actually looking for the best set list, as you are simply looking for a number of good set lists.
That being said, your problem reminds me a lot of using particle filters for trying to locate where something is.
Tweaking the method a fair bit gives something like this:
- Randomly generate 100 set lists using weighted probability. It might be useful to have some of those picked by hand.
- Calculate the scores for each set list, then use those as weights to randomly select 10 set lists.
- For each of those set lists, randomly generate 10 songs using weighted probability. For example, you might use the score of the song as a weight to determine if should you change it or not (low relative score means more likely for the song to be changed).
- Repeat steps two and three as desired.
- Pick the current best, or randomly select one of the current 100.
I used an example of 100, but you can use pretty much any sample size under probably a million or so unless you got a lot of time to let it run. Just be careful of how many you select VS how many you generate from those selected. The number selected times the number generated should equal the number you originally started with.
Not sure your familiar with weighted probability so I should probably summarize as it's rather important to the algorithm. Say you have songs A-C, with weights 1-3 respectively. One way to handle weighted probability is instead of randomly picking 100 elements from [A,B,C] (which is unweighted), you actually randomly pick 100 elements from [A,B,B,C,C,C]. Since the weight of C is 3x that of A, it is is 3x as likely to be picked.
Ideally, if you're using that method, you should keep the scores as integers, and they should be relatively low (so that the max length of the list to pick the elements from doesn't get too high). If you don't mind loss of precision (which for this case is probably fine), you can also normalize the probabilities and use that create a list that will be much more predictable in terms of how large it is. This can be done by summing the weights, then divide each by the sum, then multiply all of the results by a single number. So for example if you had weights of [1000,10000,100000] instead of 1-3, dividing each by the sum (111000) yields approximately [0.009,0.090,0.901], which times by say 100 (which gives a list size of about 100) and rounding to the nearest whole number gives: [1,9,90] Thus your list from which you randomly choose elements should contain exactly 1 A's, 9 B's and 90 C's. There's a chance that only A would be selected for re-sampling (step 3), but that's rather unlikely, although it would be problematic if it occurred. In which case, you'd probably have to re-run the program. There are ways you could get around that, but you'd end up losing a lot of the randomness of the algorithm.
Oh and adding on to 3) When changing a song, calculate the score for every song that could replace that song. Remove all songs that are of lower weight or perhaps just below some fraction of it's weight*, then use the scores as weights and randomly pick the new song that will replace it (which may actually be the same song if the score is rather high).
*This is optional, but probably not a bad idea to implement if you think it might be useful as you could just set it to below 0.0 * the weight.