# Advantage of memoization in recursive solution to Longest Common Subsequence

I was reading an article on solving the problem of `Longest Common Subsequence` at geekforgeeks, where there are two solutions, one recursive, and another through DP by a 2-D array. The DP solution does it in `O(NM)` time, while the recursive one does it in `O(2^N)` time.

The main problem with the recursive solution is the occurrence of overlapping of subsequences, as given there. however, if I store each pair in a hash, so that the next time that value is required by a recursion of the function, it can directly fetch the value from the hash instead of recursing further. So how much will this addition improve the efficiency? Will it come to `O(NM)`?

And secondly, how come the recursive solution yields `O(2^N)` time? How to find out the complexity of recursive functions like this one, or the one to find Fibonacci sequence, etc?

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Yes, using a hash will make it `O(NM)`. The process, in this case, is called memoization (yes, without the `r`). Just make sure you don't use an actual hashmap container as provided by your language of choice, make it a simple matrix: if the value for the current pair is `-1`, compute it recursively, otherwise assume it is already computed and return it.

``````                f(n)
/    \
f(n-1)      f(n-2)
/     \
f(n-2)       f(n-3)
...
``````

This should be enough to inductively suggest that it will be `O(2^n)`: the tree has height `n`, and at each node, you have two recursive calls that will reduce the problem from size `n` to size `n - 1` (which will be `O(2^(n - 1)`). So the size `n` original problem will be `O(2^n)`.

Note that it is not incorrect to say that fibonacci is `O(2^n)`, but you can get a tighter bound with other mathematical methods.

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That's interesting. Imagine I am using something like a dictionary in Python or hash in Perl. What advantage will using a 2-D array give me over either one? –  Cupidvogel Sep 27 '12 at 20:23
@Cupidvogel - I don't know how a dictionary is implemented in those languages, but there are two ways: using a tree (Red-black or AVL usually), which will add a `log size` factor into your complexity, or using an actual hash function, which will be `O(1)` on average, but might be `O(n)` in the worst case, and it will have overhead too even on average. Either way, this will be slower than checking and writing to the entry of a matrix. –  IVlad Sep 27 '12 at 20:29
Right. That's cool. But regarding the improvement, can you prove that memoization will reduce the complexity to `O(NM)`? –  Cupidvogel Sep 27 '12 at 20:32
@Cupidvogel - yes: each function call for an argument pair `(x, y)` will calculate the value only once, then save it. Subsequent calls for the same arguments will check if it is calculated (`O(1)` if using a matrix in your case), and if yes, return that value. You would need to access `DP_Array[x, y]` in your DP matrix in the iterative solution anyway, which would also be `O(1)`, so the two are equivalent complexity-wise. –  IVlad Sep 27 '12 at 20:36
@Cupidvogel - in general, the answer is also very general: use math :P. Sometimes drawing the recursion tree like I did with fibonacci will make it obvious, other times it might not. A lot of times the master theorem(google it) will work. Other times it won't and you'll need other theorems. There's no way to give a general answer I'm afraid, it depends on the actual recursive function. –  IVlad Sep 27 '12 at 20:41