I had to implement the QuickSort algorithm for a homework in a language of my choice and I chose Python.
During the lectures, we've been told that QuickSort is memory efficient because it works in-place; i.e., it has no additional copies of parts of the input array for recursions.
With this in mind, I tried to implement the QuickSort algorithm in Python, but shortly afterwards realized that in order to write an elegant piece of code I would have to pass parts of the array to the function itself while recursing. Since Python creates new lists each time I do this, I have tried using Python3 (because it supports the nonlocal keyword). The following is my commented code.
def quicksort2(array): # Create a local copy of array. arr = array def sort(start, end): # Base case condition if not start < end: return # Make it known to the inner function that we will work on arr # from the outer definition nonlocal arr i = start + 1 j = start + 1 # Choosing the pivot as the first element of the working part # part of arr pivot = arr[start] # Start partitioning while j <= end: if arr[j] < pivot: temp = arr[i] arr[i] = arr[j] arr[j] = temp i += 1 j += 1 temp = arr[start] arr[start] = arr[i - 1] arr[i - 1] = temp # End partitioning # Finally recurse on both partitions sort(start + 0, i - 2) sort(i, end) sort(0, len(array) - 1)
Now, I'm not sure whether I did the job well or am I missing something. I have written a more Pythonic version of QuickSort but that surely doesn't work in-place because it keeps returning parts of the input array and concatenates them.
My question is, is this the way of doing it in Python? I have searched both Google and SO but haven't found a true in-place implementation of QuickSort, so I thought it'd be best to ask.