The sliding window algorithm suggested by Artem Volkhin's answer is of `O(n)`

complexity.

### Advantages

- Very fast -
`O(n)`

, single pass.
- Iteration is always forward directed - can be used with linked lists.
- In-place, memory-efficient.
- No calculation overhead - best case is O(1).

### Disadvantages

- All numbers should be > 1, as it relies on the fact that the multiplication increases as we move the second pointer forward.

### Python implementation

```
def sliding_window(seq, n):
low,high=0,0 # Low index, High index
cur_sum=seq[low]
while high<=len(seq):
if cur_sum==n: # Match found, return indices
return low, high
elif cur_sum<n: # Sum to low, increase high index
high+=1
cur_sum*=seq[high]
else:
cur_sum/=seq[low] # Sum to high, increase low index
low+=1
return None, None # No match, Return
```

### Example

```
>>> ls=range(1,11)
>>> print ls
[1, 2, 3, 4, 5, 6, 7, 8, 9, 10]
>>>
>>> N=336 # 6*7*8
>>> print sliding_window(ls, N)
(5, 7) # Indices
```

`arr1`

. So P will always be 1. If you change the line to`P*=arr0[i]`

, you still have a problem - it will only find subarrays that ended at the last index. You would need an inner loop from i+1..n to find other subarrays. – AShelly Apr 7 '11 at 14:04