I have an array of N numbers which are same.I am applying Quick sort on it. What should be the time complexity of the sorting in this case.
I goggled around this question but did not get the exact explanation.
Any help would be appreciated.
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I have an array of N numbers which are same.I am applying Quick sort on it. What should be the time complexity of the sorting in this case.
I goggled around this question but did not get the exact explanation.
Any help would be appreciated.
This depends on the implementation of Quicksort. The traditional implementation which partitions into 2 (<
and >=
) sections will have O(n*n)
on identical input. While no swaps will necessarily occur, it will cause n
recursive calls to be made - each of which need to make a comparison with the pivot and n-recursionDepth
elements. i.e. O(n*n)
comparisons need to be made
However there is a simple variant which partitions into 3 sets (<
, =
and >
). This variant has O(n)
performance in this case - instead of choosing the pivot, swapping and then recursing on 0
to pivotIndex-1
and pivotIndex+1
to n
, it will put swap all things equal to the pivot to the 'middle' partition (which in the case of all identical inputs always means swapping with itself i.e. a no-op) meaning the call stack will only be 1 deep in this particular case n comparisons and no swaps occur. I believe this variant has made its way into the standard library on linux at least.
<=
and >=
sections, distributing the equal values evenly between them. This has no cost in the average case (distinct data) and guarantees O(N log N) time in the case of equal data
– comocomocomocomo
Sep 9 '13 at 6:31
The performance of quicksort depends on the pivot selection. The closer the chosen pivot is to the median element, the better is quicksort's performance.
In this specific case you're lucky - the pivot you select will always be a median, since all values are the same. The partition step of quicksort will hence never have to swap elements, and the two pointers will meet exactly in the middle. The two subproblems will have therefore be exactly half the size - giving you a perfect O(n log n)
.
To be a little more specific, this depends on how well the partition step is implemented. The loop-invariant only needs to make sure that smaller elements are in the left-hand sub-problem, while greater elements are in the right-hand sub-problem. There's no guarantee that a partition implementation never swaps equal elements. But it is always unnecessary work, so no clever implementation should do it: The left
and right
pointers will never detect an inversion respective the pivot (i.e. you will never hit the case where *left > pivot && *right < pivot
) and so the left
pointer will be incremented, the right
pointer will be decremented every step and they will finally meet in the middle, generating subproblems of size n/2
.
n*n
performance in the specific case he is talking about - all elements the same.
– tobyodavies
Feb 26 '11 at 12:26
<
and >=
so while no swaps will occur, it will recurse n*n
times and do nothing but recurse each time, still leading to n*n
performance
– tobyodavies
Feb 26 '11 at 12:33
<
and >=
, you will can even get infinite recursion with the equals-elements case. (all elements will will always be on the right side, the subproblem never shrinks).
– ltjax
Feb 26 '11 at 13:23
It depends on the particular implementation.
If there is only one kind of comparison (≤ or <) to determine where the other elements go relative to the pivot, they will all go into one of the partitions, and you will get O(n^{2}) performance, since the problem size will decrease by only 1 each step.
The algorithm listed here is an example (the accompanying illustration are for a different algorithm).
If there are two kinds of comparisons, for example < for elements on the left and > for elements on the right, as is the case in a two-pointer implementation, and if you take care to move the pointers in step, then you might get perfect O(n log n) performance, because half the equal elements will be split evenly in the two partitions.
The illustrations in the link above use an algorithm which doesn't move pointers in step, so you still get poor performance (look at the "Few unique" case).
So it depends whether you have this special case in mind when implementing the algorithm.
Practical implementations often handle a broader special case: if there are no swaps in the partitioning step, they assume the data is nearly sorted, and use an insertion sort, which gives an even better O(n) in the case of all equal elements.
O(n)
not O(n log n)
in this case - each pointer just gets incremented until the end, max n
comparisons
– tobyodavies
Feb 26 '11 at 13:03
=
partition
– tobyodavies
Feb 26 '11 at 13:56
<
and >
(as opposed to <
and >=
) doesn't partition into 3 - if you are doing <
and >
, the =
s have to go somewhere...
– tobyodavies
Feb 26 '11 at 15:32
tobyodavies has provided the right solution. It does handle the case and finish in O(n) time when all the keys are equal. It is the same partitioning as we do in dutch national flag problem
http://en.wikipedia.org/wiki/Dutch_national_flag_problem
Sharing the code from princeton
http://algs4.cs.princeton.edu/23quicksort/Quick3way.java.html
If you implement the 2-way partitioning algorithm then at every step the array will be halved. This is because when identical keys will be encountered, the scan stops. As a result at each step, the partitioning element will be positioned at the center of the subarray thereby halving the array in every subsequent recursive call. Now, this case is similar to the mergesort case which uses ~N lg N
compares to sort an array of N elements. Ergo for duplicate keys, the traditional 2-way partitioning algorithm for Quicksort uses ~N lg N
compares, thereby following a linearithmic approach.
Quick Sort code is done using "partition" and "quicksort" functions.
Basically, there are two best ways for implementing Quicksort.
The difference between these two is only the "partition" function,
1.Lomuto
2.Hoare
With a partitioning algorithm such as the Lomuto partition scheme described above (even one that chooses good pivot values), quicksort exhibits poor performance for inputs that contain many repeated elements. The problem is clearly apparent when all the input elements are equal: at each recursion, the left partition is empty (no input values are less than the pivot), and the right partition has only decreased by one element (the pivot is removed). Consequently, the Lomuto partition scheme takes quadratic time to sort an array of equal values.
So, this takes O(n^2) time using the Lomuto partition algorithm.
By using the Hoare partition algorithm we get the best case with all the array elements equal. The time complexity is O(n).
Reference: https://en.wikipedia.org/wiki/Quicksort