This python code is a modification of QuickSort:

```
def findDuplicate(arr):
orig_len = len(arr)
if orig_len <= 1:
return None
pivot = arr.pop(0)
greater = [i for i in arr if i > pivot]
lesser = [i for i in arr if i < pivot]
if len(greater) + len(lesser) != orig_len - 1:
return pivot
else:
return findDuplicate(lesser) or findDuplicate(greater)
```

It finds a duplicate in O(n logn)), I think. It uses extra memory on the stack, but it can be rewritten to use only one copy of the original data, I believe:

```
def findDuplicate(arr):
orig_len = len(arr)
if orig_len <= 1:
return None
pivot = arr.pop(0)
greater = [arr.pop(i) for i in reversed(range(len(arr))) if arr[i] > pivot]
lesser = [arr.pop(i) for i in reversed(range(len(arr))) if arr[i] < pivot]
if len(arr):
return pivot
else:
return findDuplicate(lesser) or findDuplicate(greater)
```

The list comprehensions that produce *greater* and *lesser* destroy the original with calls to pop(). If *arr* is not empty after removing *greater* and *lesser* from it, then there must be a duplicate and it must be *pivot*.

The code suffers from the usual stack overflow problems on sorted data, so either a random pivot or an iterative solution which queues the data is necessary:

```
def findDuplicate(full):
import copy
q = [full]
while len(q):
arr = copy.copy(q.pop(0))
orig_len = len(arr)
if orig_len > 1:
pivot = arr.pop(0)
greater = [arr.pop(i) for i in reversed(range(len(arr))) if arr[i] > pivot]
lesser = [arr.pop(i) for i in reversed(range(len(arr))) if arr[i] < pivot]
if len(arr):
return pivot
else:
q.append(greater)
q.append(lesser)
return None
```

However, now the code needs to take a deep copy of the data at the top of the loop, changing the memory requirements.

So much for computer science. The naive algorithm clobbers my code in python, probably because of python's sorting algorithm:

```
def findDuplicate(arr):
arr = sorted(arr)
prev = arr.pop(0)
for element in arr:
if element == prev:
return prev
else:
prev = element
return None
```