I have this code which computes the Longest Common Subsequence between random strings to see how accurately one can reconstruct an unknown region of the input. To get good statistics I need to iterate it many times but my current python implementation is far too slow. Even using pypy it currently takes 21 seconds to run once and I would ideally like to run it 100s of times.

```
#!/usr/bin/python
import random
import itertools
#test to see how many different unknowns are compatible with a set of LCS answers.
def lcs(x, y):
n = len(x)
m = len(y)
# table is the dynamic programming table
table = [list(itertools.repeat(0, n+1)) for _ in xrange(m+1)]
for i in range(n+1): # i=0,1,...,n
for j in range(m+1): # j=0,1,...,m
if i == 0 or j == 0:
table[i][j] = 0
elif x[i-1] == y[j-1]:
table[i][j] = table[i-1][j-1] + 1
else:
table[i][j] = max(table[i-1][j], table[i][j-1])
# Now, table[n, m] is the length of LCS of x and y.
return table[n][m]
def lcses(pattern, text):
return [lcs(pattern, text[i:i+2*l]) for i in xrange(0,l)]
l = 15
#Create the pattern
pattern = [random.choice('01') for i in xrange(2*l)]
#create text start and end and unknown.
start = [random.choice('01') for i in xrange(l)]
end = [random.choice('01') for i in xrange(l)]
unknown = [random.choice('01') for i in xrange(l)]
lcslist= lcses(pattern, start+unknown+end)
count = 0
for test in itertools.product('01',repeat = l):
test=list(test)
testlist = lcses(pattern, start+test+end)
if (testlist == lcslist):
count += 1
print count
```

I tried converting it to numpy but I must have done it badly as it actually ran more slowly. Can this code be sped up a lot somehow?

**Update.** Following a comment below, it would be better if `lcses`

used a recurrence directly which gave the LCS between `pattern`

and all sublists of `text`

of the same length. Is it possible to modify the classic dynamic programming LCS algorithm somehow to do this?