/Sorting

Primary LanguagePython

Sorting Algorithms

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.

No Googling for Code

For the sorting module, it's OK to Google for things like this:

  • Pseudocode
  • Descriptions of algorithms
  • Videos that show how the algorithm works

But you should NOT search for:

  • Code

If you see code, avert your eyes and hit the back button!

This isn't for anti-cheating purposes. This is because if you copy code, you won't learn the most important part of this lesson! One of the things we want to practice here is to take a spec and turn it into code. You'll be expected to do this incessantly at work, and we want to practice it here. Yes, it's harder this way, but you don't get better by practicing easy stuff.

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.

That being said, please still use the 20 minute rule 🙂

Part 1

MVP Tasks

  • Open up the iterative_sorting directory
  • Read through the descriptions of the bubble_sort and selection_sort algorithms
  • Implement bubble_sort and selection_sort in iterative_sorting.py
  • Test your implementation by running test_iterative.py

Part 2

MVP Tasks

  • Open up the recursive_sorting directory
  • Read through the descriptions of the merge_sort algorithm
  • Implement merge_sort in recursive_sorting.py
  • Test your implementation by running test_recursive.py

Stretch Goals

  • Implement all the methods in the searching.py file in the searching directory.
  • Implement the count_sort algorithm in the iterative_sorting directory.
  • Implement an in-place version of merge_sort that does not allocate any additional memory. In other words, the space complexity for this function should be O(1).
  • Implement the timsort algorithm, which is a real-world sorting algorithm. In fact, it is the sorting algorithm that is used when you run Python's built-in sort method.