I've designed an algorithm to find the longest common subsequence. these are steps:

Pick the first letter in the first string.

Look for it in the second string and if its found, Add that letter to

`common_subsequence`

and store its position in`index`

, Otherwise compare the length of`common_subsequence`

with the length of`lcs`

and if its greater, asign its value to`lcs`

.Return to the first string and pick the next letter and repeat the previous step again, But this time start searching from

`index`

th letterRepeat this process until there is no letter in the first string to pick. At the end the value of

`lcs`

is the Longest Common Subsequence.

This is an example:

```
X=A, B, C, B, D, A, B
Y=B, D, C, A, B, A
```

Pick `A`

in the first string.

Look for `A`

in `Y`

.

Now that there is an `A`

in the second string, append it to `common_subsequence`

.

Return to the first string and pick the next letter that is `B`

.
Look for `B`

in the second string this time starting from the position of `A`

.

There is a `B`

after `A`

so append B to `common_subsequence`

.

Now pick the next letter in the first string that is `C`

. There isn't a `C`

next to `B`

in the second string. So assign the value of common_subsequence to `lcs`

because its length is greater than the length of `lcs`

.
repeat the previous steps until reaching the end of the first string. In the end the value of `lcs`

is the Longest Common Subsequence.

The complexity of this algorithm is theta(n*m). Here is my implementations:

First algorithm:

```
import time
def lcs(xstr, ystr):
if not (xstr and ystr): return # if string is empty
lcs = [''] # longest common subsequence
lcslen = 0 # length of longest common subsequence so far
for i in xrange(len(xstr)):
cs = '' # common subsequence
start = 0 # start position in ystr
for item in xstr[i:]:
index = ystr.find(item, start) # position at the common letter
if index != -1: # if common letter has found
cs += item # add common letter to the cs
start = index + 1
if index == len(ystr) - 1: break # if reached end of the ystr
# update lcs and lcslen if found better cs
if len(cs) > lcslen: lcs, lcslen = [cs], len(cs)
elif len(cs) == lcslen: lcs.append(cs)
return lcs
file1 = open('/home/saji/file1')
file2 = open('/home/saji/file2')
xstr = file1.read()
ystr = file2.read()
start = time.time()
lcss = lcs(xstr, ystr)
elapsed = (time.time() - start)
print elapsed
```

The same algorithm using hash table:

```
import time
from collections import defaultdict
def lcs(xstr, ystr):
if not (xstr and ystr): return # if strings are empty
lcs = [''] # longest common subsequence
lcslen = 0 # length of longest common subsequence so far
location = defaultdict(list) # keeps track of items in the ystr
i = 0
for k in ystr:
location[k].append(i)
i += 1
for i in xrange(len(xstr)):
cs = '' # common subsequence
index = -1
reached_index = defaultdict(int)
for item in xstr[i:]:
for new_index in location[item][reached_index[item]:]:
reached_index[item] += 1
if index < new_index:
cs += item # add item to the cs
index = new_index
break
if index == len(ystr) - 1: break # if reached end of the ystr
# update lcs and lcslen if found better cs
if len(cs) > lcslen: lcs, lcslen = [cs], len(cs)
elif len(cs) == lcslen: lcs.append(cs)
return lcs
file1 = open('/home/saji/file1')
file2 = open('/home/saji/file2')
xstr = file1.read()
ystr = file2.read()
start = time.time()
lcss = lcs(xstr, ystr)
elapsed = (time.time() - start)
print elapsed
```

`None`

, so don't check if`len(str)`

is 0, just check that`not str`

. – Latty Dec 31 '12 at 23:18