The speed of the search depends on several factors:

- the length of the string
- the position before which there is not a one-time-occuring character
- the size of the string after this position
- the number of different characters occuring in the string

.

In the following code, I firstly define a string `s`

with the help of `random.choice()`

and the a group of one-time-occurring characters named `unik`

,

from two strings `s1`

and `s2`

that I concatenate : `s1 + s2`

where:

`s1`

is a string of length `nwo`

in which there is NOT ANY one-time-occurring character
`s2`

is a string of length `nwi`

in which THERE IS one-time-occurring characters

.

```
#### creation of s from s1 and s2 #########
from random import choice
def without(u,n):
letters = list('abcdefghijklmnopqrstuvwxyz')
for i in xrange(n):
c = choice(letters)
if c not in unik:
yield c
def with_un(u,n):
letters = list('abcdefghijklmnopqrstuvwxyz')
ecr = []
for i in xrange(n):
c = choice(letters)
#ecr.append('%d %s len(letters) == %d' % (i,c,len(letters)))
yield c
if c in unik:
letters.remove(c)
#print '\n'.join(ecr)
unik = 'ekprw'
nwo,nwi = 0,500
s1 = ''.join(c for c in without(unik,nwo))
s2 = ''.join(c for c in with_un(unik,nwi))
s = s1 + s2
if s1:
print '%-27ss2 : %d chars' % ('s1 : %d chars' % len(s1),len(s2))
for el in 'ekprw':
print ('s1.count(%s) == %-12ds2.count(%s) == %d'
% (el,s1.count(el),el,s2.count(el)))
others = [c for c in 'abcdefghijklmnopqrstuvwxyz' if c not in unik]
print 's1.count(others)>1 %s' % all(s1.count(c)>1 for c in others)
else:
print "s1 == '' len(s2) == %d" % len(s2)
for el in 'ekprw':
print (' - s2.count(%s) == %d'
% (el,s2.count(el)))
print 'len of s == %d\n' % len(s)
```

Then there is the benchmarking.

Varying the numbers `nwo`

and `nwi`

we see the influence on the speed:

```
### benchmark of three solutions #################
from time import clock
# Janne Karila
from collections import Counter, OrderedDict
class OrderedCounter(Counter, OrderedDict):
pass
te = clock()
c = OrderedCounter(s)
rjk = (item for item, count in c.iteritems() if count == 1).next()
tf = clock()-te
print 'Janne Karila %.5f found: %s' % (tf,rjk)
# eyquem
te = clock()
candidates = set(s)
li = []
for x in s:
if x in candidates:
li.append(x)
candidates.remove(x)
elif x in li:
li.remove(x)
rey = li[0]
tf = clock()-te
print 'eyquem %.5f found: %s' % (tf,rey)
# TyrantWave
te = clock()
rty = (a for a in s if s.count(a) == 1).next()
tf = clock()-te
print 'TyrantWave %.5f found: %s' % (tf,rty)
```

.

Some results

With `s1`

of null length, nwo = 0 and nwi = 50:

```
s1 == '' len(s2) == 50
- s2.count(e) == 1
- s2.count(k) == 1
- s2.count(p) == 1
- s2.count(r) == 1
- s2.count(w) == 1
len of s == 50
Janne Karila 0.00077 found: e
eyquem 0.00013 found: e
TyrantWave 0.00005 found: e
```

TyrantWave's solutions is the faster because the first one-occurring-char is found rapidly in the first positions of the string

.

With nwo = 300 and nwi = 50

(hereafter 401 chars for `s1`

because occurrences of one-time-occurring chars weren't retained during construct of `s1`

, see function without() )

```
s1 : 245 chars s2 : 50 chars
s1.count(e) == 0 s2.count(e) == 1
s1.count(k) == 0 s2.count(k) == 1
s1.count(p) == 0 s2.count(p) == 1
s1.count(r) == 0 s2.count(r) == 1
s1.count(w) == 0 s2.count(w) == 1
s1.count(others)>1 True
len of s == 295
Janne Karila 0.00167 found: e
eyquem 0.00030 found: e
TyrantWave 0.00042 found: e
```

This time TyrantWave's solution is longer than mine because it has to count occurrences of all the characters in the first part of `s`

that is to say in `s1`

in which there are no one-time-occurring characters (they are in the second part `s2`

)

However, to obtain a more short time with my solution, `nwo`

needs to be notably greater than `nwi`

.

With nwo = 300 and nwi = 5000

```
s1 : 240 chars s2 : 5000 chars
s1.count(e) == 0 s2.count(e) == 1
s1.count(k) == 0 s2.count(k) == 1
s1.count(p) == 0 s2.count(p) == 1
s1.count(r) == 0 s2.count(r) == 1
s1.count(w) == 0 s2.count(w) == 1
s1.count(others)>1 True
len of s == 5240
Janne Karila 0.01510 found: p
eyquem 0.00534 found: p
TyrantWave 0.00294 found: p
```

If length of `s2`

is raised, then TyrantWave's solution is better again.

.

Conclude what you want

.

### EDIT

Terrific idea of Roman !

I added the solution of Roman in my benchmarking, and it won !

I also did some tiny modifications that improve his solution.

```
# Roman Fursenko
srf = s[:]
te = clock()
while srf != "":
slen0 = len(srf)
ch = srf[0]
srf = srf.replace(ch, "")
slen1 = len(srf)
if slen1 == slen0-1:
rrf = ch
break
else:
rrf = "No answer"
tf = clock()-te
print 'Roman Fursenko %.6f found: %s' % (tf,rrf)
# Roman Fursenko improved
srf = s[:]
te = clock()
while not(srf is ""):
slen0 = len(srf)
srf = srf.replace(srf[0], "")
if len(srf) == slen0-1:
rrf = ch
break
else:
rrf = "No answer"
tf = clock()-te
print 'Roman improved %.6f found: %s' % (tf,rrf)
print '\nindex of %s in the string : %d' % (rty,s.index(rrf))
```

.

The results are:

.

```
s1 == '' len(s2) == 50
- s2.count(e) == 1
- s2.count(k) == 1
- s2.count(p) == 1
- s2.count(r) == 1
- s2.count(w) == 1
len of s == 50
Janne Karila 0.0032538 found: r
eyquem 0.0001249 found: r
TyrantWave 0.0000534 found: r
Roman Fursenko 0.0000299 found: r
Roman improved 0.0000263 found: r
index of r in the string : 1
```

```
s1 == '' len(s2) == 50
- s2.count(e) == 1
- s2.count(k) == 0
- s2.count(p) == 1
- s2.count(r) == 1
- s2.count(w) == 1
len of s == 50
Janne Karila 0.0008183 found: a
eyquem 0.0001285 found: a
TyrantWave 0.0000550 found: a
Roman Fursenko 0.0000433 found: a
Roman improved 0.0000391 found: a
index of a in the string : 4
```

>

```
s1 : 240 chars s2 : 50 chars
s1.count(e) == 0 s2.count(e) == 1
s1.count(k) == 0 s2.count(k) == 0
s1.count(p) == 0 s2.count(p) == 1
s1.count(r) == 0 s2.count(r) == 1
s1.count(w) == 0 s2.count(w) == 1
s1.count(others)>1 True
len of s == 290
Janne Karila 0.0016390 found: e
eyquem 0.0002956 found: e
TyrantWave 0.0004112 found: e
Roman Fursenko 0.0001428 found: e
Roman improved 0.0001277 found: e
index of e in the string : 242
```

```
s1 : 241 chars s2 : 5000 chars
s1.count(e) == 0 s2.count(e) == 1
s1.count(k) == 0 s2.count(k) == 1
s1.count(p) == 0 s2.count(p) == 1
s1.count(r) == 0 s2.count(r) == 1
s1.count(w) == 0 s2.count(w) == 1
s1.count(others)>1 True
len of s == 5241
Janne Karila 0.0148231 found: r
eyquem 0.0053283 found: r
TyrantWave 0.0030166 found: r
Roman Fursenko 0.0007414 found: r
Roman improved 0.0007230 found: r
index of r in the string : 250
```

I've learned something thanks to the code of Roman:

`s.replace()`

creates a new string and I thought that, because of that, it was a slow method.

But, I don't know for which reason, it is a really fast method.

.

### EDIT 2

The Oin's solution is worst:

```
# Oin
from operator import itemgetter
seen = set()
only_appear_once = dict()
te = clock()
for i, x in enumerate(s):
if x in seen and x in only_appear_once:
only_appear_once.pop(x)
else:
seen.add(x)
only_appear_once[x] = i
fco = min(only_appear_once.items(),key=itemgetter(1))[0]
tf = clock()-te
print 'Oin %.7f found: %s' % (tf,fco)
```

results

```
s1 == '' len(s2) == 50
Oin 0.0007124 found: e
Janne Karila 0.0008057 found: e
eyquem 0.0001252 found: e
TyrantWave 0.0000712 found: e
Roman Fursenko 0.0000335 found: e
Roman improved 0.0000335 found: e
index of e in the string : 2
s1 : 237 chars s2 : 50 chars
Oin 0.0029783 found: k
Janne Karila 0.0014714 found: k
eyquem 0.0002889 found: k
TyrantWave 0.0005598 found: k
Roman Fursenko 0.0001458 found: k
Roman improved 0.0001372 found: k
index of k in the string : 246
s1 : 236 chars s2 : 5000 chars
Oin 0.0801739 found: e
Janne Karila 0.0155715 found: e
eyquem 0.0044623 found: e
TyrantWave 0.0027548 found: e
Roman Fursenko 0.0007255 found: e
Roman improved 0.0007199 found: e
index of e in the string : 244
```