I'm presenting a problem my professor showed in class, with my O(n*log(n)) solution:

Given a list of `n`

numbers we'd like to perform the following `n-1`

times:

- Extract the two minimal elements
`x,y`

from the list and present them - Create a new number
`z`

, where`z = x+y`

- Put
`z`

back into the list

Suggest a data structure and algorithm for `O(n*log(n))`

, and `O(n)`

Solution:

We'll use a minimal heap:

Creating the heap one time only would take O(n). After that, extracting the two minimal elements would take O(log(n)). Placing `z`

into the heap would take O(log(n)).

Performing the above `n-1`

times would take O(n*log(n)), since:

```
O(n)+O(n∙(logn+logn ))=O(n)+O(n∙logn )=O(n∙logn )
```

But how can I do it in O(n)?

**EDIT:**

By saying: "extract the two minimal elements `x,y`

from the list and **present them** ", I mean `printf("%d,%d" , x,y)`

, where `x`

and `y`

are the smallest elements in the current list.

someoperation on the scale of O(n) times. To achieve an overall O(n) time, you'd need that operation to be O(1). You can find the two minimum values in O(1) time in a sorted list, but injecting a value back into the list and maintaining the sort would be log(n). Unless you want to get into radix sort, but that's a bit fishy. – cheeken Jun 19 '12 at 0:49`z`

into the list, you stick a flag on it to say "this is a computed value, not an original value". Suppose finally that when you present the numbers, you only print out the ones with the flag unset. Then you have sorted your list of numbers in`O(n)`

. Therefore, some kind of skullduggery is required, such as for example radix sort on fixed-size integers. – Steve Jessop Jun 19 '12 at 0:52