# How to find the Longest Common Subsequence in Exponential time?

I can do this the proper way using dynamic programming but I can't figure out how to do it in exponential time.

I'm looking to find the largest common sub-sequence between two strings. Note: I mean subsequences and not sub-strings the symbols that make up a sequence need not be consecutive.

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`A naive exponential algorithm is to notice that a string of length n has O(2n) different subsequences, so we can take the shorter string, and test each of its subsequences for presence in the other string, greedily.`: algorithmist.com/index.php/Longest_Common_Subsequence I hope this is helpful. –  ChristopheD Jan 25 '12 at 21:23
why would you want exponential runtime when you have dynamic programming approach working? –  Adrian Jan 25 '12 at 21:23
Its a potential exam question I have to be prepared for. –  Deco Jan 25 '12 at 21:27

Just replace the lookups in the table in your dynamic programming code with recursive calls. In other words, just implement the recursive formulation of the LCS problem:

EDIT

In pseudocode (almost-python, actually):

``````def lcs(s1, s2):
if len(s1)==0 or len(s2)==0: return 0
if s1[0] == s2[0]: return 1 + lcs(s1[1:], s2[1:])
return max(lcs(s1, s2[1:]), lcs(s1[1:], s2))
``````
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What would this be in Pseudo code? I can't make out what that means. –  Deco Jan 25 '12 at 21:32
@Deco added pseudocode :) note that it returns the length of LCS(s1, s2), you can easily patch it to keep track of the inedexes (ie. when s1[0] == s2[0] –  Savino Sguera Jan 25 '12 at 22:18

Essentially if you don't use dynamic programming paradigm - you reach exponential time. This is because, by not storing your partial values - you are recomputing the partial values multiple times.

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Let's say you have two strings `a` and `b` of length `n`. The longest common subsequence is going to be the longest subsequence in string `a` that is also present in string `b`.

Thus we can iterate through all possible subsequences in `a` and see it is in `b`.

A high-level pseudocode for this would be:

``````for i=n to 0
for all length i subsequences s of a
if s is a subsequence of b
return s
``````
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@NiklasB. Could you give a counter-example to illustrate your claim? –  tskuzzy Feb 27 '12 at 9:49
Damn, I think I made a mistake here. I'd remove my downvote, but it's locked :/ Sorry. –  Niklas B. Feb 27 '12 at 14:13
No worries, as long as that's cleared up :) –  tskuzzy Feb 27 '12 at 15:03

String A and String B. A recursive algorithm, maybe it's naive but it is simple:

Look at the first letter of A. This will either be in a common sequence or not. When considering the 'not' option, we trim off the first letter and call recursively. When considering the 'is in a common sequence' option we also trim it off and we also trim off from the start of B up to, and including, the same letter in B. Some pseudocode:

``````def common_subsequences(A,B, len_subsequence_so_far = 0):
if len(A) == 0 or len(B) == 0:
return
first_of_A = A[0] // the first letter in A.
A1 = A[1:] // A, but with the first letter removed
common_subsequences(A1,B,len_subsequence_so_far) // the first recursive call
if(the_first_letter_of_A_is_also_in_B):
Bn = ... delete from the start of B up to, and including,
... the first letter which equals first_of_A
common_subsequences(A1,Bn, 1+len_subsequence_so_far )
``````

You could start with that and then optimize by remembering the longest subsequence found so far, and then returning early when the current function cannot beat that (i.e. when `min(len(A), len(B))+len_subsequence_so_far` is smaller than the longest length found so far.

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