I had underestimated your question, but it actually isn't easy to answer. There are a lot of different elements to consider.

Doing `lst.insert(y, lst.pop(x))`

is a `O(n)`

operation, because `lst.pop(x)`

costs `O(len(lst) - x)`

since list elements must be contiguous, and thus the list has to shift-left by one all the elements after index `x`

, and dually `lst.insert(y, _)`

costs `O(len(lst) - y)`

since it has to shift all the elements right by one.

This means that a naive analysis can give an upperbound of O(n^3) complexity in the worst case for your code. As you suggested this is actually correct [remember that O(n^2) is a *subset* of O(n^3)], however it's not a *tight* upperbound because you swap each element only once. So for `n`

times you do `n`

work, and this complexity is indeed O(n * n + n^2) = O(n^2), where the second n^2 refers to the number of comparisons which is n^2 in the worst case. So, asymptotically your solution is the same as insertion sort.

The first algorithm and the second algorithm change the order of iterations over the `y`

. As I have already commented this *changes the worst-case* for the algorithm.
While insertion sort has its worst-case with reverse-sorted sequences, your algorithm doesn't (which is actually good). This *might* be a factor that adds to the difference in timings since if you do *not* use random lists you might use an input that is worst-case for one algorithm but not worst-case for the other.

```
In [2]: %timeit insertionSort(list(range(10)))
100000 loops, best of 3: 5.46 us per loop
In [3]: %timeit myInsertionSort(list(range(10)))
100000 loops, best of 3: 8.47 us per loop
In [4]: %timeit insertionSort(list(reversed(range(10))))
10000 loops, best of 3: 20.4 us per loop
In [5]: %timeit myInsertionSort(list(reversed(range(10))))
100000 loops, best of 3: 9.81 us per loop
```

You should always tests with (also) random inputs with different lengths.

The average complexity of insertion sort is O(n^2). Your algorithm *might* have a lower average time, however it's not entirely trivial to compute it.

I don't get why you use the `insert+pop`

at all when you can use the swap. Trying this on my machine yields a quite big improvement in efficiency since you reduce an O(n^2) component to a O(n) component.

Now, you ask why there was such a big change between the execution at home and in class.
There can be various reasons, for example if you did not use a random generated list you might have used an almost best-case input for insertion sort while it was an almost worst-case input for your algorithm. And similar considerations. Without seeing what you did in class is not possible to give an exact answer.

*However* I believe there is a *very* simple answer: you forgot to copy the list before profiling. This is the *same* error *I* did when I first posted this answer (quote from the previous answer):

If you want to compare the two functions you should use *random*
lists:

```
In [6]: import random
...: input_list = list(range(10))
...: random.shuffle(input_list)
...:
In [7]: %timeit insertionSort(input_list) # Note: no input_list[:]!! Argh!
100000 loops, best of 3: 4.82 us per loop
In [8]: %timeit myInsertionSort(input_list)
100000 loops, best of 3: 7.71 us per loop
```

Also you should use big inputs to see the difference clearly:

```
In [11]: input_list = list(range(1000))
...: random.shuffle(input_list)
In [12]: %timeit insertionSort(input_list) # Note: no input_list[:]! Argh!
1000 loops, best of 3: 508 us per loop
In [13]: %timeit myInsertionSort(input_list)
10 loops, best of 3: 55.7 ms per loop
```

Note also that I, unfortunately, always executed the pairs of profilings in the same order, confirming my previous ideas.

As you can see all calls to `insertionSort`

except the first one used a sorted list as input, which is the *best-case* for insertion-sort! This means that the timing for insertion sort is wrong (and I'm sorry for having written this before!) While `myInsertionSort`

was always executed with an already sorted list, and guess what? Turns out that one of the worst-cases for `myInsertionSort`

is *the sorted list*!
think about it:

```
for x in range(len(alist)):
for y in range(x):
if alist[y]>alist[x]:
alist.insert(y,alist.pop(x))
break
```

If you have a sorted list the `alist[y] > alist[x]`

comparison will always be false. You might say "perfect! no swaps => no O(n) work => better timing", unfortunately this is false because no swaps also mean no `break`

and hence you are doing `n*(n+1)/2`

iterations, i.e. the worst-case performance.

Note that **this is very bad**!!! Real-world data *really often* is partially sorted, so an algorithm whose worst-case is the sorted list is usually *not a good algorithm* for real-world use.

Note that this does *not* change if you replace `insert + pop`

with a simple swap, hence the algorithm itself is not good from this point of view, independently from the implementation.

`n`

and`1`

are the complexities of the insert+pop and swap]. Note that saying "I tried and mine was x times faster" isuseless, because you run the code with a particular input, while efficiency is about "global performances" that hold for all inputs or for a certain class of inputs. – Bakuriu Nov 22 '13 at 12:25`test = range(1000); random.shuffle(test); copy1, copy2 = test, test[:]`

, then feed`copy1`

and`copy2`

to your functions to compare them. – Martijn Pieters♦ Nov 22 '13 at 12:29notonly the swap vs insert+pop, but also the order in which you do the operations. The`y`

are iterated in reverse order in the two functions this might affect performance (think about it: normal insertion sort has best case when data is sorted and worst case when the data is sorted backwards, so reversing elementsdoeschange the efficiency of the algorithm. comparing the two functions on the same input mightnotbe a "fair" comparison, since the input might be worst case for one and not-worst-case for the other) – Bakuriu Nov 22 '13 at 12:31