So I have a typical recursive implementation of a problem that requires a 1-0 knapsack problem-like solution. Here's the code for the main function:

```
def knapsack(items,sizeLimit):
P = {}
def recurse(nItems,lim):
if not P.has_key((nItems,lim)):
if nItems == 0:
P[nItems,lim] = 0
elif itemSize(items[nItems-1]) > lim:
P[nItems,lim] = recurse(nItems-1,lim)
else:
P[nItems,lim] = max(recurse(nItems-1,lim),
recurse(nItems-1,lim-itemSize(items[nItems-1])) +
itemValue(items[nItems-1]))
return P[nItems,lim]
return recurse(len(items),sizeLimit)
```

The problem is that I have millions upon millions of pieces of data, and it seems like this approach will calculate every entry, leading to obvious memory and speed problems. Is there some kind of dynamic programming/memoization technique I could use to further optimize this implementation?

`O(n)`

space saved for the stack trace? The space complexity of both solutions is`O(n*W)`

(where in this case`W = lim`

). The iterative DP algorithm is basically a buttom-up DP solution of the same recursive formula. – amit Dec 23 '12 at 17:24