The speaker is wrong in this case. The actual cost is `O(n * log(t))`

. Heapify is called only on the first `t`

elements of the iterable. That's `O(t)`

, but is insignificant if `t`

is much smaller than `n`

. Then all the remaining elements are added to this "little heap" via `heappushpop`

, one at a time. That takes `O(log(t))`

time per invocation of `heappushpop`

. The length of the heap remains `t`

throughout. At the very end, the heap is sorted, which costs `O(t * log(t))`

, but that's also insignificant if `t`

is much smaller than `n`

.

## Fun with Theory ;-)

There are reasonably easy ways to find the t'th-largest element in expected `O(n)`

time; for example, see here. There are harder ways to do it in worst-case `O(n)`

time. Then, in another pass over the input, you could output the `t`

elements >= the t-th largest (with tedious complications in case of duplicates). So the whole job *can* be done in `O(n)`

time.

But those ways require `O(n)`

memory too. Python doesn't use them. An advantage of what's actually implemented is that the worst-case "extra" memory burden is `O(t)`

, and that can be very significant when the input is, for example, a generator producing a great many values.

`nlargest`

with`t=n`

to comparison sort a list in linear time. If you just want the`t`

largest elements inanyorder, that can be done in O(n) with quickselect.`heapq.nlargest`

doesn't use quickselect, though; it gives the items in sorted order with a heap-based algorithm. – user2357112 Apr 13 '14 at 3:51