# USACO — Dynamic Programming — Longest Common Subsequence

I've used this recursive relation to solve this classic problem. Here it is:

``````if (I == n || J == m)
dp[I][J] = 0;<br>
else if (x[I] == y[J])
dp[I][J] = dp[I+1][J+1] + 1;<br>
else
dp[I][J] = max (dp[I+1][J], dp[I][J+1]);
``````

but I've seen the USACO TEXT about Dynamic Programming, that it used this pseudocode for this problem:

``````    # the tail of the second sequence is empty
1   for element = 1 to length1
2     length[element, length2+1] = 0

# the tail of the first sequence has one element
3   matchelem = 0
4   for element = length2 to 1
5     if list1[length1] = list2[element]
6       matchelem = 1
7     length[length1,element] = nmatchlen

# loop over the beginning of the tail of the first sequence
8   for loc = length1-1 to 1
9     maxlen = 0
10     for element = length2 to 1

# longest common subsequence doesn't include first element
11       if length[loc+1,element] > maxlen
12         maxlen = length[loc+1,element]

# longest common subsequence includes first element
13       if list1[loc] = list2[element] &&
14                       length[loc+1,element+1]+1 > maxlen
15           maxlen = length[loc,element+1] + 1

16     length[loc,element] = maxlen
``````

It it a bit different with my solution. Instead of `dp[I][J] = max (dp[I+1][J], dp[I][J+1]);` , it's used below code.

``````    # longest common subsequence doesn't include first element
11       if length[loc+1,element] > maxlen
12         maxlen = length[loc+1,element]
``````

Why this solution just checks `length[loc+1,element]` and doesn't check `length[loc,element+1]`? Does this solution guarantee to find the correct answer?

Please guide me to get this point! Thanks for you help...

-