# Are there any worse sorting algorithms than Bogosort (a.k.a Monkey Sort)?

My co-workers took me back in time to my University days with a discussion of sorting algorithms this morning. We reminisced about our favorites like StupidSort, and one of us was sure we had seen a sort algorithm that was O(n!). That got me started looking around for the "worst" sorting algorithms I could find.

We postulated that a completely random sort would be pretty bad (i.e. randomize the elements - is it in order? no? randomize again), and I looked around and found out that it's apparently called BogoSort, or Monkey Sort, or sometimes just Random Sort.

Monkey Sort appears to have a worst case performance of O(∞), a best case performance of O(n), and an average performance of O(n·n!).

Are there any named algorithms that have worse average performance than O(n·n!)? Or are just sillier than Monkey Sort in general?

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How many bogomips per bogosort? Inquiring minds want to know. –  zombat Apr 9 '10 at 18:30
To clarify, are you excluding the trivial case where best case performance is O(∞)? –  tloflin Apr 9 '10 at 18:42
@tloflin - generally yeah, I assume any named algorithm would have to have a remote chance of success. I'll clarify the question a bit - are there any algorithms that are worse than n*n! on average? –  womp Apr 9 '10 at 18:51
I heard that the monkey sort is also known as "drunk man sort", a name that I find much more evocative. –  Matteo Italia Apr 9 '10 at 19:44

Intelligent Design Sort

Introduction

Intelligent design sort is a sorting algorithm based on the theory of intelligent design.

Algorithm Description

The probability of the original input list being in the exact order it's in is 1/(n!). There is such a small likelihood of this that it's clearly absurd to say that this happened by chance, so it must have been consciously put in that order by an intelligent Sorter. Therefore it's safe to assume that it's already optimally Sorted in some way that transcends our naïve mortal understanding of "ascending order". Any attempt to change that order to conform to our own preconceptions would actually make it less sorted.

Analysis

This algorithm is constant in time, and sorts the list in-place, requiring no additional memory at all. In fact, it doesn't even require any of that suspicious technological computer stuff. Praise the Sorter!

Feedback

Gary Rogers writes:

Making the sort constant in time denies the power of The Sorter. The Sorter exists outside of time, thus the sort is timeless. To require time to validate the sort dimishes the role of the Sorter. Thus... this particular sort is flawed, and can not be attributed to 'The Sorter'.

Heresy!

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Also known as "Assumption Sort": Assume the list is sorted, return! –  BioGeek Apr 9 '10 at 19:42
+100 - this answer is made out of 100% pure win. –  womp Apr 9 '10 at 19:48
Hey! Don't forget "Indecisive Sort" (Also know as "Schrodinger's Sort" or "Quantum Sort"), where the list may or may not be sorted, however checking it will reveal whether or not it is. Here is my sample implementation: void quantum_sort (void *b, size_t n, size_t s, int (*c)(const void *, const void*)) { if (rand () % 2) qsort (b, n, s, c); }. –  Joe D Aug 29 '10 at 18:50

Many years ago, I invented (but never actually implemented) MiracleSort.

Start with an array in memory.
loop:
Check to see whether it's sorted.
Yes? We're done.
No? Wait a while and check again.
end loop


Eventually, alpha particles flipping bits in the memory chips should result in a successful sort.

For greater reliability, copy the array to a shielded location, and check potentially sorted arrays against the original.

So how do you check the potentially sorted array against the original? You just sort each array and check whether they match. MiracleSort is the obvious algorithm to use for this step.

EDIT: Strictly speaking, this is not an algorithm, since it's not guaranteed to terminate. Does "not an algorithm" qualify as "a worse algorithm"?

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I assume one can use cosmic rays to prove correctness of this algorithm. –  ghord Nov 25 '12 at 9:57
What's the big O of this? O(2^N)? –  Mooing Duck Dec 14 '12 at 17:50
@MooingDuck: I don't think it actually has a big O. –  Keith Thompson Feb 21 '13 at 18:17
There are many algorithms which are not guaranteed to terminate (Bogosort for one). I'm think this algorithm's average case is O(2^N), since each bit in the dataset halves the odds of success each round (but I'm not betting money on being right). You're right that technically it's big-O-infinity since it may not terminate. –  Mooing Duck Feb 21 '13 at 19:15
@MooingDuck: Strictly speaking, if it doesn't terminate it's not an algorithm, according to both what they taught me in college and the Wikipedia article. –  Keith Thompson Feb 21 '13 at 19:39

Quantum Bogosort

A sorting algorithm that assumes that the many-worlds interpretation of quantum mechanics is correct:

1. Check that the list is sorted. If not, destroy the universe.

At the conclusion of the algorithm, the list will be sorted in the only universe left standing. This algorithm takes worst-case O(N) and average-case O(1) time. In fact, the average number of comparisons performed is 2: there's a 50% chance that the universe will be destroyed on the second element, a 25% chance that it'll be destroyed on the third, and so on.

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But time ceases to exist in the universe you just destroyed. So an observer in a universe that you have not yet checked will not be able to tell how much of the algorithm has been executed. Thus, this algorithm always takes O(1) time, since previous universe-destructions don't exist anymore. –  Barry Brown Apr 9 '10 at 20:09
Yes, in the only universe that observes the list sorted, it took O(n) time to execute - how long it took in other universes is irrelevant. –  Nick Johnson Apr 10 '10 at 11:26
There will be many universes left standing. In some of them the list is sorted and Obama gets the Nobel Peace Prize for keeping Guantanamo open. In some of them the list is sorted and Obama gets the Nobel Peace Prize for closing Guantanamo. –  Windows programmer Apr 19 '10 at 4:26
This algorithm has a much bigger problem, however. Assume that one in 10 billion times you will mistakenly conclude a list is sorted when it's not. There are 20! ways to sort a 20 element list. After the sort, the remaining universes will be the one in which the list was sorted correctly, and the 2.4 million universes in which the algorithm mistakenly concluded the list was sorted correctly. So what you have here is an algorithm for massively magnifying the error rate of a piece of machinery. –  Nick Johnson Oct 11 '11 at 23:19
This is obviously the best sorting algorithm, not the worst. –  Boann Nov 25 '12 at 12:54

If you keep the algorithm meaningful in any way, O(n!) is the worst upper bound you can achieve.

Since checking each possibility for a permutations of a set to be sorted will take n! steps, you can't get any worse than that.

If you're doing more steps than that then the algorithm has no real useful purpose. Not to mention the following simple sorting algorithm with O(infinity):

list = someList
while (list not sorted):
doNothing

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But it takes O(n) to check whether it's sorted, so you can get O(n*n!) –  erikkallen Apr 9 '10 at 19:29
@erikkallen: Certainly we can come up with an algorithm to verify sortedness that's worse than O(n). For example, for each element in the array, verify that it's greater than all previous ones, much like insertion sort works. That's an O(n^2) algorithm, and I'm sure I could come up with worse given a little thought. –  David Thornley Apr 9 '10 at 20:21
@David Thornley: the following checking algorithm would perhaps show the same spirit as the bogosort: pick two random elements, check that the one with the smaller index is smaller or equal to the one with the larger index, then repeat. Keep a square bit matrix to see which combinations have already been checked. Of course, checking this matrix could also be done in a random walk... –  Svante Apr 9 '10 at 20:47

I had a lecturer who once suggested generating a random array, checking if it was sorted and then checking if the data was the same as the array to be sorted.

Best case O(N) (first time baby!) Worst case O(Never)

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More interesting to analyze is the average case, which is...? –  Mooing Duck Dec 14 '12 at 17:52
As all the best text books say, this is left as an exercise for the reader! –  Daniel Dec 16 '12 at 0:42
Mooing Duck: O(sometimes) –  Ilya O. Mar 5 '13 at 2:51
@MooingDuck then we need to know cardinality of element type and distribution used to generate random elements in random arrays. –  Sarge Borsch May 27 '13 at 15:57

I'm surprised no one has mentioned sleepsort yet... Or haven't I noticed it? Anyway:

#!/bin/bash
function f() {
sleep "$1" echo "$1"
}
while [ -n "$1" ] do f "$1" &
shift
done
wait


example usage:

./sleepsort.sh 5 3 6 3 6 3 1 4 7
./sleepsort.sh 8864569 7


In terms of performance it is terrible (especially the second example). Waiting almost 3.5 months to sort 2 numbers is kinda bad.

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This appears to be an O(N) sort, but in truth is constrained by however the OS implements timers. –  Mooing Duck Dec 14 '12 at 17:53
Any way you cut it, this is probably exhibits a better growth than bogosort. –  Mooing Duck Dec 16 '12 at 1:49
I see a race condition there. –  user142019 Mar 7 '13 at 21:58

You should do some research into the exciting field of Pessimal Algorithms and Simplexity Analysis. These authors work on the problem of developing a sort with a pessimal best-case (your bogosort's best case is Omega(n), while slowsort (see paper) has a non-polynomial best-case time complexity).

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Here's 2 sorts I came up with my roommate in college

1) Check the order 2) Maybe a miracle happened, go to 1

and

1) check if it is in order, if not 2) put each element into a packet and bounce it off a distant server back to yourself. Some of those packets will return in a different order, so go to 1

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The second is almost the equivalent of a bozo sort. First is clever though. –  Mooing Duck Dec 14 '12 at 17:54

Nothing can be worse than infinity.

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Infinity + 1. Jinx, no returns. –  zombat Apr 9 '10 at 18:31
Not for extremely large values of 1 ;) –  zombat Apr 9 '10 at 18:53
What really blows my mind about the concept of infinity, is that you can have different "sizes" of infinity. For example, consider the set of all integers - it is infinite in size. Now consider the set of all even integers - it is also infinite in size, but it is also clearly half the size of the first set. Both infinite, but different sizes. So awesome. The concept of "size" simply fails to work in the context of infinity. –  zombat Apr 9 '10 at 19:54
@zombat: You're talking about cardinality, not infinity as a symbol indicating a trend on the real line / complex plane. –  KennyTM Apr 9 '10 at 20:15
@zombat. The size of the set of even integers is the same as the size of the set of the integers, as shown by the fact that you can place them in one-to-one correspondence. Now, there are more real numbers than integers, as first shown by Cantor. –  David Thornley Apr 9 '10 at 20:19

1 Put your items to be sorted on index cards
2 Throw them into the air on a windy day, a mile from your house.
2 Throw them into a bonfire and confirm they are completely destroyed.
3 Check your kitchen floor for the correct ordering.
4 Repeat if it's not the correct order.

Best case scenerio is O(∞)

Edit above based on astute observation by KennyTM.

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Isn't this BogoSort? –  Steve Apr 9 '10 at 18:28
No, this is worse because there's no chance of it succeeding. How would the index cards get into your kitchen? They're blowing around outside. It's called, uh, buttheadsort. –  Patrick Karcher Apr 9 '10 at 18:31
@Patrick Quantum tunneling. –  KennyTM Apr 9 '10 at 18:39
@KennyTM. That had actually occurred to me. There is an extremely small but non-zero chance that any object might disappear and reappear at any other point in the universe. I guess it could happen to a thousand index cards . . . Oi. Dangit, my algorithm is flawed. I'll fix it . . . –  Patrick Karcher Apr 9 '10 at 18:49
It's kind of like having tea and no tea at the same time. Or space travel using an infinite improbability drive. –  Barry Brown Apr 9 '10 at 19:33
show 1 more comment

Bozo sort is a related algorithm that checks if the list is sorted and, if not, swaps two items at random. It has the same best and worst case performances, but I would intuitively expect the average case to be longer than Bogosort. It's hard to find (or produce) any data on performance of this algorithm.

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Jingle Sort, as described here.

You give each value in your list to a different child on Christmas. Children, being awful human beings, will compare the value of their gifts and sort themselves accordingly.

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A worst case performance of O(∞) might not even make it an algorithm according to some.

An algorithm is just a series of steps and you can always do worse by tweaking it a little bit to get the desired output in more steps than it was previously taking. One could purposely put the knowledge of the number of steps taken into the algorithm and make it terminate and produce the correct output only after X number of steps have been done. That X could very well be of the order of O(n2) or O(nn!) or whatever the algorithm desired to do. That would effectively increase its best-case as well as average case bounds.

But your worst-case scenario cannot be topped :)

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My favorite slow sorting algorithm is the stooge sort:

void stooges(long *begin, long *end) {
if( (end-begin) <= 1 ) return;
if( begin[0] < end[-1] ) swap(begin, end-1);
if( (end-begin) > 1 ) {
int one_third = (end-begin)/3;
stooges(begin, end-one_third);
stooges(begin+one_third, end);
stooges(begin, end-one_third);
}
}


The worst case complexity is O(n^(log(3) / log(1.5))) = O(n^2.7095...).

Another slow sorting algorithm is actually named slowsort!

void slow(long *start, long *end) {
if( (end-start) <= 1 ) return;
long *middle = start + (end-start)/2;
slow(start, middle);
slow(middle, end);
if( middle[-1] > end[-1] ) swap(middle-1, end-1);
slow(start, end-1);
}


This one takes O(n ^ (log n)) in the best case... even slower than stoogesort.

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My personal favorite is Tom Duff's sillysort:

/*
* The time complexity of this thing is O(n^(a log n))
* for some constant a. This is a multiply and surrender
* algorithm: one that continues multiplying subproblems
* as long as possible until their solution can no longer
* be postponed.
*/
void sillysort(int a[], int i, int j){
int t, m;
for(;i!=j;--j){
m=(i+j)/2;
sillysort(a, i, m);
sillysort(a, m+1, j);
if(a[m]>a[j]){ t=a[m]; a[m]=a[j]; a[j]=t; }
}
}

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There's always the Bogobogosort (Bogoception!). It performs Bogosort on increasingly large subsets of the list, and then starts all over again if the list is ever not sorted.

for (int n=1; n<sizeof(list); ++n) {
while (!isInOrder(list, 0, n)) {
shuffle(list, 0, n);
}
if (!isInOrder(list, 0, n+1)) { n=0; }
}

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I like the idea that this algorithm is designed to never finish "before the heat death of the universe for any sizeable list" –  A.Grandt Feb 22 at 9:36

One I was just working on involves picking two random points, and if they are in the wrong order, reversing the entire subrange between them. I found the algorithm on http://richardhartersworld.com/cri_d/cri/2001/badsort.html, which says that the average case is is probably somewhere around O(n^3) or O(n^2 log n) (he's not really sure).

I think it might be possible to do it more efficiently, because I think it might be possible to do the reversal operation in O(1) time.

Actually, I just realized that doing that would make the whole thing I say maybe because I just realized that the data structure I had in mind would put accessing the random elements at O(log n) and determining if it needs reversing at O(n).

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Bogobogosort. Yes, it's a thing. to Bogobogosort, you Bogosort the first element. Check to see if that one element is sorted. Being one element, it will be. Then you add the second element, and Bogosort those two until it's sorted. Then you add one more element, then Bogosort. Continue adding elements and Bogosorting until you have finally done every element. This was designed never to succeed with any sizable list before the heat death of the universe.

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You could make any sort algorithm slower by running your "is it sorted" step randomly. Something like:

1. Create an array of booleans the same size as the array you're sorting. Set them all to false.
2. Run an iteration of bogosort
3. Pick two random elements.
4. If the two elements are sorted in relation to eachother (i < j && array[i] < array[j]), mark the indexes of both on the boolean array to true. Overwise, start over.
5. Check if all of the booleans in the array are true. If not, go back to 3.
6. Done.
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Yes, SimpleSort, in theory it runs in O(-1) however this is equivalent to O(...9999) which is in turn equivalent to O(∞ - 1), which as it happens is also equivalent to O(∞). Here is my sample implementation:

/* element sizes are uneeded, they are assumed */
void
simplesort (const void* begin, const void* end)
{
for (;;);
}

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Double bogosort

Bogosort twice and compare results (just to be sure it is sorted) if not do it again

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Randomsubsetsort.

Given an array of n elements, choose each element with probability 1/n, randomize these elements, and check if the array is sorted. Repeat until sorted.

Expected time is left as an exercise for the reader.

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## The "what would you like it to be?" sort

1. Note the system time.
2. Sort using Quicksort (or anything else reasonably sensible), omitting the very last swap.
3. Note the system time.
4. Calculate the required time. Extended precision arithmetic is a requirement.
5. Wait the required time.
6. Perform the last swap.

Not only can it implement any conceivable O(x) value short of infinity, the time taken is provably correct (if you can wait that long).

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