mateo815/phase-4-data-structures-implement-a-stack

Implement a Stack Lab

Learning Goals

• Implement a Stack using an array as the underlying data structure

Introduction

In the previous lesson, you learned what a Stack is and what methods they commonly include. In this lab, you will be building out an implementation of a Stack. You will be using an array as the underlying data structure, and calling on some built-in Ruby array methods to build your Stack class's functionality.

Start by forking and cloning this lab. You'll be writing your code in the lib/stack.rb file. You can run the tests at any point using learn test to check your work.

Instructions

First, create the Stack class and set it up to initialize an instance variable @stack that points to an empty array.

Once you have the first test passing, build out the following methods:

• Stack#push(value): add an element to the top of the stack
• Stack#pop: remove the element at the top of the stack
• Stack#peek: return the value of the element at the top of the stack without removing it

Bonus

If you'd like an extra challenge, try implementing the additional functionality below. There are tests for these in the spec/stack_spec.rb file; uncomment the bonus methods section in the test file to try these out.

1. Modify your Stack#initialize method to take an optional limit value and set that as an attribute.

2. Update the Stack#push value to only push the passed-in value if there's still room in the Stack. If the Stack is full, the method should throw an error.

3. Implement the following additional methods:

• Stack#size: returns the number of elements contained in the Stack
• Stack#empty?: returns true if the Stack is empty; false otherwise
• Stack#full?: returns true if the Stack is full; false otherwise
• Stack#search(value): returns the distance between the top of the stack and the target element if it's present; -1 otherwise

After you've made these changes, you might want to take another look through your code and see if there's any refactoring you can do.

Conclusion

In this lesson, we got some practice building a data structure from scratch by implementing a Stack class. Recall that the runtime of our data structure will depend on what data structure it uses under the hood. For this lab, we used an array as the underlying data structure, which means the runtime for the #search method is O(n), and the runtime for all of the other methods is O(1).

While our implementation is efficient in terms of time complexity, we have to consider space complexity as well. One of the characteristics of an Array is that each of the elements can be accessed directly using the [] operator. In order for this to work, all the elements need to be stored in a continuous block of memory. If we're trying to add an element and we're out of memory where the array is located, the entire array will need to be relocated. This is expensive in terms of memory, which means using an array as our underlying data structure is not optimal from the perspective of space complexity. Refer to this lesson for a more comprehensive explanation of space and time efficiency issues with arrays.

Given that a Stack only uses push and pop methods, we don't need to use an underlying data structure that allows direct access to all of the elements. A better choice is a LinkedList, because it uses a hash as its underlying data structure and hashes do not need to be stored in a continuous block of memory. The LinkedList is the next data structure we'll learn about. Before we get to that, however, let's get a little practice using Stacks.