# Why is builtin sorted() slower for a list containing descending numbers if each number appears twice consecutively?

I sorted four similar lists. List `d` consistently takes much longer than the others, which all take about the same time:

``````a:  33.5 ms
b:  33.4 ms
c:  36.4 ms
d: 110.9 ms
``````

Why is that?

Test script (Attempt This Online!):

``````from timeit import repeat

n = 2_000_000
a = [i // 1 for i in range(n)]  # [0, 1, 2, 3, ..., 1_999_999]
b = [i // 2 for i in range(n)]  # [0, 0, 1, 1, 2, 2, ..., 999_999]
c = a[::-1]                     # [1_999_999, ..., 3, 2, 1, 0]
d = b[::-1]                     # [999_999, ..., 2, 2, 1, 1, 0, 0]

for name in 'abcd':
lst = globals()[name]
time = min(repeat(lambda: sorted(lst), number=1))
print(f'{name}: {time*1e3 :5.1f} ms')
``````
• Sorting algorithms have certain ideal and certain worst cases. It's entirely possible that list is simply hitting the worst case.
– deceze
Mar 5 at 15:25
• @deceze In that case, it's weird that c is fast while d is slow since both are just in reverse order. You'd think those would hit the same case category. Perhaps the real question is "Why is sorting list c fast?" Mar 5 at 15:27
• @deceze Ah, giving it a better look. D is actually different from C as there are repeated elements in D, so they are not the same case. Mar 5 at 15:29
• Anyone who wants to dig in might want to start with bugs.python.org/file4451/timsort.txt, which is a detailed explanation of Python's sorting algorithm. Mar 5 at 15:30
• Early hypothesis: might have to do with `count_runs`. `a` and `b` detect the whole list as a single ascending run (`lo[0] <= lo[1] <= lo[2] <= ...`); `c` detects the whole list as a single descending run (`lo[0] > lo[1] > lo[2] > ...`); but `d` detects a million ascending (e.g. `10 <= 10`) or descending (e.g. `10 > 9`) runs of size 2. (I have not looked further yet, but this is a rather large difference in the inputs) Mar 5 at 15:41

As alluded to in the comments by btilly and Amadan, this is due to how the Timsort sorting algorithm works. Detailed description of the algorithm is here.

Timsort speeds up operation on partially sorted arrays by identifying runs of sorted elements.

A run is either "ascending", which means non-decreasing:

a0 <= a1 <= a2 <= ...

or "descending", which means strictly decreasing:

a0 > a1 > a2 > ...

Note that a run is always at least 2 long, unless we start at the array's last element.

Your arrays a, b and c each consist of just one run. The array d has 1 million runs.

The reason why the descending run cannot be `>=` is to make the sort stable, i.e. keep the order of equal elements:

The definition of descending is strict, because the main routine reverses a descending run in-place, transforming a descending run into an ascending run. Reversal is done via the obvious fast "swap elements starting at each end, and converge at the middle" method, and that can violate stability if the slice contains any equal elements. Using a strict definition of descending ensures that a descending run contains distinct elements.

Python 3.11 has slightly improved version of timsort, sometimes called powersort, but it uses the same run detection and thus has the same performance.

• @MartinKealey In general, Python places ease of use in front of speed - an interpreted language will never be terribly fast. At the point when Timsort was introduced, Python had already used a stable sort for a decade, changing it would have broken compatibility.
– jpa
Mar 6 at 6:40
• I'm the guy who wrote almost all of CPython's sorts. No sort implementation in CPython was guaranteed stable before "timsort". No platform offers a stable `qsort()` by default (all ways of making quicksort stable require more memory and/or time than basic quicksort). For any non-stable sorting algoithm, there are probably specific inputs it leaves stable - "by accident". Mar 6 at 18:50
• That would be slower than you're guessing ;-) The sort only uses `__lt__()` comparisons, so equality cannot be detected directly. Establishing that `x == y` (which the algorithm never needs to do now) would have to follow as a deduction from establishing `not x < y and not y < x`. So how is establishing that `x <= y` for ascending runs done? As a deduction from establishing `not y < x`, a single `__lt__()` comparison (and if it's not the case that `not y < x`, then it's established that the run is (strictly) desciending). Mar 8 at 17:38
• I won't pursue it - aimed at a contrived case, and would complicate the code at the cost of slowing other cases. For example, `[2, 1] * 1000000`. As is, each time we hit a 1, `2 < 1?` says "no" and we get out of "descending mode" at once. But with the change, every time we'd also need to ask "OK, 1 < 2?" to determine whether or not they were equal. Leaving "descending mode" would always require 2 compares (but needs only 1 now). Add more complications to keep track of the last time an all-equal run started, etc - gets less attractive with each new detail. Mar 8 at 20:48
• On third thought ;-) , I'm warming to this, and opened an issue on CPython's tracker: github.com/python/cpython/issues/116554 Mar 10 at 2:22

As @jpa's answer explained, `a`, `b` and `c` have a single "run" while `d` has a million. We can also see the effect of that by counting the comparisons:

``````a:  1999999 comparisons, 1.000 per element
b:  1999999 comparisons, 1.000 per element
c:  1999999 comparisons, 1.000 per element
d: 10710650 comparisons, 5.355 per element
``````

A single long run means we only compare each pair of neighbors once, that's all. For n elements, that's n-1 comparisons.

Since `a` and `b` are ascending, they're already sorted, and nothing further is done. Since `c` is descending, it simply gets reversed, and then nothing further is done.

For `d`, the two-element runs first get combined into runs of 32 to 64 elements using binary insertion sort. And then these longer runs get merged again and again into larger and larger runs until the whole list is sorted.

I tried various values of n. The number of comparisons for `d` hovered around 5 per element, going up to ~5.3 until n reached a power of 2, after which the number of comparisons fell to ~4.7 again. In general, `d` requires O(n) comparisons. It doesn't need n log n comparisons, because the merging uses "galloping" (an exponential search), which in this case needs only logarithmically many comparisons. So unlike ordinary merge sort in general cases, the recurrence relation for the number of comparisons here isn't `T(n) = 2T(n/2) + n` but `T(n) = 2T(n/2) + log(n)`, which is O(n).

The runtime however isn't O(n), as there are still n log n moves of elements. But that's low-level and very fast, relatively fast compared to the O(n) slower comparisons. If you measure time for various n, you might very well think it's O(n) time.

The script for counting (Attempt This Online!):

``````n = 2_000_000
a = [i // 1 for i in range(n)]
b = [i // 2 for i in range(n)]
c = a[::-1]
d = b[::-1]

class Int:
def __init__(self, value):
self.value = value
def __lt__(self, other):
global comparisons
comparisons += 1
return self.value < other.value

for name in 'abcd':
lst = globals()[name]
comparisons = 0
sorted(map(Int, lst))
print(f'{name}: {comparisons} comparisons, {comparisons/len(lst) :5.3f} per element')
``````