A simple quadratic time solution would be this:

```
res = []
n = len(lst)
for i in xrange(n):
if not any(i != j and lst[i] in lst[j] for j in xrange(n)):
res.append(lst[i])
```

But we can do much better:

Let `$`

be a character that does not appear in any of your strings and has a lower value than all your actual characters.

Let `S`

be the concatenation of all your strings, with `$`

in between. In your example, `S = a$abc$b$d$xy$xyz`

.

You can build the suffix array of `S`

in linear time. You can also use a much simpler O(n log^2 n) construction algorithm that I described in another answer.

Now for every string in `lst`

, check if it occurs in the suffix array exactly once. You can do two binary searches to find the locations of the substring, they form a contiguous range in the suffix array. If the string occurs more than once, you remove it.

With LCP information precomputed, this can be done in linear time as well.

Example O(n log^2 n) implementation, adapted from my suffix array answer:

```
def findFirst(lo, hi, pred):
""" Find the first i in range(lo, hi) with pred(i) == True.
Requires pred to be a monotone. If there is no such i, return hi. """
while lo < hi:
mid = (lo + hi) // 2
if pred(mid): hi = mid;
else: lo = mid + 1
return lo
# uses the algorithm described in http://stackoverflow.com/a/21342145/916657
class SuffixArray(object):
def __init__(self, s):
""" build the suffix array of s in O(n log^2 n) where n = len(s). """
n = len(s)
log2 = 0
while (1<<log2) < n:
log2 += 1
rank = [[0]*n for _ in xrange(log2)]
for i in xrange(n):
rank[0][i] = s[i]
L = [0]*n
for step in xrange(1, log2):
length = 1 << step
for i in xrange(n):
L[i] = (rank[step - 1][i],
rank[step - 1][i + length // 2] if i + length // 2 < n else -1,
i)
L.sort()
for i in xrange(n):
rank[step][L[i][2]] = \
rank[step][L[i - 1][2]] if i > 0 and L[i][:2] == L[i-1][:2] else i
self.log2 = log2
self.rank = rank
self.sa = [l[2] for l in L]
self.s = s
self.rev = [0]*n
for i, j in enumerate(self.sa):
self.rev[j] = i
def lcp(self, x, y):
""" compute the longest common prefix of s[x:] and s[y:] in O(log n). """
n = len(self.s)
if x == y:
return n - x
ret = 0
for k in xrange(self.log2 - 1, -1, -1):
if x >= n or y >= n:
break
if self.rank[k][x] == self.rank[k][y]:
x += 1<<k
y += 1<<k
ret += 1<<k
return ret
def compareSubstrings(self, x, lx, y, ly):
""" compare substrings s[x:x+lx] and s[y:y+yl] in O(log n). """
l = min((self.lcp(x, y), lx, ly))
if l == lx == ly: return 0
if l == lx: return -1
if l == ly: return 1
return cmp(self.s[x + l], self.s[y + l])
def count(self, x, l):
""" count occurences of substring s[x:x+l] in O(log n). """
n = len(self.s)
cs = self.compareSubstrings
lo = findFirst(0, n, lambda i: cs(self.sa[i], min(l, n - self.sa[i]), x, l) >= 0)
hi = findFirst(0, n, lambda i: cs(self.sa[i], min(l, n - self.sa[i]), x, l) > 0)
return hi - lo
def debug(self):
""" print the suffix array for debugging purposes. """
for i, j in enumerate(self.sa):
print str(i).ljust(4), self.s[j:], self.lcp(self.sa[i], self.sa[i-1]) if i >0 else "n/a"
def filterSublist(lst):
splitter = "\x00"
s = splitter.join(lst) + splitter
sa = SuffixArray(s)
res = []
offset = 0
for x in lst:
if sa.count(offset, len(x)) == 1:
res.append(x)
offset += len(x) + 1
return res
```

However, the interpretation overhead likely causes this to be slower than the O(n^2) approaches unless `S`

is really large (in the order of 10^5 characters or more).

`lst`

? – Niklas B. May 26 '14 at 11:21`b`

should be part of the output, but it's not – Niklas B. May 26 '14 at 12:23