I think the "naïve" solution the presenter is briefly mentioning has runtime complexity *O(KS)*, given the way he defined *K* to be the sum of all the item limits. The idea is to convert it into a 0/1 problem by making *k*_{i} copies of each item type.

Assume you've got *k*_{0} items of type 0, *k*_{1} items of type 1, and so on (so those are the limits to how many items you may take of each type). *K* is the total number of items (the sum of all the *k*_{i}). Now, if you take this collection of items and start considering *every* item to be distinct from all the others, you have a 0/1 problem! The first item of type 0 is now item 0 in our new problem, the second item of type 0 is item 1 in our new problem, the last item of type 0 is item *k*_{0} - 1 in our new problem - and they all have weight *w*_{0} and value *v*_{0}. The first item of type 1 is item *k*_{0} in our new problem, and so on. So we can now solve this as a 0/1 knapsack problem, but it's got *K* items instead of *n*; thus, the complexity is *O(KS)*. However, if you define *K* to be the *average* of all the *k*_{i}, or if every item has the same limit *K*, the complexity is indeed *O(nKS)*.