In this two day project, you will be implementing many different solutions to the same problem: sort a list of integers in ascending order. You will also be using your newfound knowledge of complexity analysis to evaluate each implementation for efficiency.
Many times in your Lambda career, we encourage you to scour the internet anytime you are stumped by a problem. This is NOT one of those cases. Yes, it is possible to Google "quicksort in Python" and find a solution in about 10 seconds but that is not the point of these exercises. Your task is to take a simple problem (sort an list of ints) and a pre-defined plan (we give you an algorithm description) and turn that into code. These steps should sound familiar, as they are 1-3 of Polya's Problem Solving techniques. Soon, you will be coming up with your own plans for more complex problems so don't cheat yourself out of valuable coding practice.
- Open up the iterative_sorting directory
- Read through the descriptions of the
bubble_sortandselection_sortalgorithms - Implement
bubble_sortandselection_sortin iterative_sorting.py - Test your implementation by running
test_iterative.py
- Open up the recursive_sorting directory
- Read through the descriptions of the
merge_sortalgorithm - Implement
merge_sortin recursive_sorting.py - Test your implementation by running
test_recursive.py
- Implement all the methods in the
searching.pyfile in thesearchingdirectory. - Implement the
count_sortalgorithm in theiterative_sortingdirectory. - Implement an in-place version of
merge_sortthat does not allocate any additional memory. In other words, the space complexity for this function should be O(1). - Implement the
timsortalgorithm, which is a real-world sorting algorithm. In fact, it is the sorting algorithm that is used when you run Python's built-insortmethod.