I think you are on the right track with using a heap data structure.

You could process the files in parallel and for each file you could maintain a min-heap of size 10.

As you iterate through a file you insert a value into the min-heap until it is full (size 10) then for values in positions 11 through n

```
if current_value > min_heap.current()
min_heap.extract()
min_heap.insert(current_value)
```

You have to iterate through n values and the worst case scenario is if the file is sorted in ascending order. In that case you will have to extract the min value and insert a new value for all the values in positions 11 thru n. The heap operations will be O(log n) giving you an overall running time of O(n * log n) for each file.

At this point you have m (# of files) min-heaps each of size 10. Here you can use a final min heap to store the ten largest numbers contained in the m min-heaps. This computation will be O(m) because the all the heaps at this point will be of max size 10, a constant.

Overall the running time will be O(n * log n + m). m could be much smaller than n so amongst friends we could say O(n * log n).

Even if you don't do the first step in parallel it would be O(m * n * log n + m), but once again if n dominates m we could say O(n * log n).