Skip to content

Latest commit

 

History

History
368 lines (210 loc) · 12.5 KB

File metadata and controls

368 lines (210 loc) · 12.5 KB

logo_ironhack_blue 7

LAB | JS Functions & Arrays


Introduction

Array manipulation is a common task in programming. Whether you are calculating a total for a shopping cart, grabbing only the first names from a list of people, or moving a piece on a chessboard, you are probably modifying or manipulating an array somewhere in the code.

Requirements

  • Fork this repo
  • Clone it to your machine

Submission

  • Upon completion, run the following commands:
git add .
git commit -m "Solved lab"
git push origin master
  • Create a Pull Request so that your TAs can check your work.

Automated Testing Introduction

What is automated testing?

Automated software testing is the process of programmatically executing an application in order to validate and verify that it meets the business needs, as well as the technical requirements, and that it behaves as expected.

Testing should be viewed as a continuous process, not a discrete operation or single activity in the development lifecycle. Designing tests at the beginning of the product lifecycle can be help to mitigate common issues that arise when developing complex code bases.

Having a strong test suite can provide you ease of mind, since you will be able to confidently improve upon your work while knowing that your not breaking a previously developed feature.

Testing labs

This LAB, along with some of the labs you will be working on during the bootcamp, is equipped with unit tests to provide automated feedback on your lab progress.

Testing with Jasmine

Jasmine is an automated testing framework for JavaScript. It is designed to be used in Behavior-driven Development (BDD) programming, which focuses more on the business value than on the technical details.

We have already included Jasmine in the project you just forked, so let's see how to use it to implement our code.

Usage

Before start coding, we will explain the project structure we have provided you:

lab-js-functions-and-arrays
  ├── README.md
  ├── SpecRunner.html
  ├── jasmine
  │   └── ...
  ├── src
  │   └── functions-and-arrays.js
  └── tests
      └── functions-and-arrays.spec.js

We will be working with the src/functions-and-arrays.js. In the jasmine folder you can find all of the files needed to use Jasmine. All these files are already linked with the SpecRunner.html file.

In case you want to check the tests, they are in the tests/functions-and-arrays.spec.js file.

Run tests

Running automated tests with Jasmine is super easy. All you need to do is open the SpecRunner.html file in your browser. You will find something similar to this:

image

Pass the tests

You should write your code on the src/functions-and-arrays.js file. While following the instructions for each iteration, you should check every test and make sure it's passing, before moving on.

Do not rush. You should take your time to carefully read every iteration, and you should address the breaking tests as you progress through the exercise.

When coding with tests, it is super important that you carefully read and understand the errors you are getting, this way you will know for sure what's expected from your code.

To see output of your JavaScript code open the Console in the Developer Tools.

Important: Note that you don't need to execute the functions yourself; the tests will automatically load and execute the functions on each test run. All you need to do is declare the functions, ensure that they handle the parameters passed, and that they return what is indicated in the iteration instructions and the test description. For some iterations we provide you with a sample array, so that you can do some manual testing, if you wish.

Instructions

While following the instructions for each iteration, make sure to carefully read the instructions and tests descriptions to fully understand the task requirements. Do not rush. You should take your time to carefully read every iteration.


Iteration #1: Find the maximum

Implement the function maxOfTwoNumbers that takes two numbers as arguments and returns the bigger number.


Iteration #2: Find the longest word

Implement the function findLongestWord that takes as an argument an array of words and returns the longest one. If there are 2 with the same length, it should return the first occurrence.

You can use the following array to test your solution:

const words = ['mystery', 'brother', 'aviator', 'crocodile', 'pearl', 'orchard', 'crackpot'];

Iteration #3: Calculate the sum

Iteration #3.1: Sum numbers

Calculating a sum can be as simple as iterating over an array and adding each of the elements together.

Implement the function named sumNumbers that takes an array of numbers as an argument, and returns the sum of all of the numbers in the array. Later in the course we will learn how to do this by using the reduce array method, which will make your work significantly easier. For now, let's practice "declarative" way adding values, using loops.

You can use the following array to test your solution:

const numbers = [6, 12, 1, 18, 13, 16, 2, 1, 8, 10];

Bonus - Iteration #3.2: A generic sum() function

The goal: Learn how to refactor your code. 💪

In the iteration 3, you created a function that returns the sum of an array of numbers. But what if we wanted to know how much is the sum of the length of all of the words in an array? What if we wanted to add boolean values to the mix? We wouldn't be able to use the same function as above, or better saying, we would have to tweak it a little bit so that it can be reused no matter what is in the array that is passed as argument when function sumNumbers() is called.

Here we are applying a concept we call polymorphism, that is, dealing with a functions' input independently of the types they are passed as.

Let's implement the function sum() that calculates the sum for array filled with (almost) any type of data. Note that strings should have their length added to the total, and boolean values should be coerced into their corresponding numeric values. Check the tests for more details.

You can use the following array to test your solution:

const mixedArr = [6, 12, 'miami', 1, true, 'barca', '200', 'lisboa', 8, 10];

// should return: 57

Iteration #4: Calculate the average

Calculating an average is a very common task. Let's practice it a bit.

The logic behind this:

  1. Find the sum as we did in the first exercise (or how about reusing that the function sumNumbers()?)
  2. Take that sum and divide it by the number of elements in the array.

Iteration #4.1: Array of numbers

Implement the function averageNumbers that expects an array of numbers and returns the average of the numbers.

You can use the following array to test your solution:

const numbers = [2, 6, 9, 10, 7, 4, 1, 9];

Iteration #4.2: Array of strings

Implement the function named averageWordLength that receives as a single argument an array of words and returns the average length of the words:

You can use the following array to test your solution:

const words = ['seat', 'correspond', 'linen', 'motif', 'hole', 'smell', 'smart', 'chaos', 'fuel', 'palace'];

Bonus - Iteration #4.3: A generic avg() function

Create function avg(arr) that receives any mixed array and calculates average. Consider as mixed array an array filled with numbers and/or strings and/or booleans.

The non-numerical values should be counted as follows:

  • Booleans: true counts as 1 and false counts as 0.
  • Strings: use the string length as the numeric value.
const mixedArr = [6, 12, 'miami', 1, true, 'barca', '200', 'lisboa', 8, 10];

// should return: 5.7

Iteration #5: Unique arrays

Take the following array, remove the duplicates, and return a new array. You are more than likely going to want to check out the Array methods indexOf and includes.

Do this in the form of a function uniquifyArray that receives an array of words as a argument.

You can use the following array to test your solution:

const words = [
  'crab',
  'poison',
  'contagious',
  'simple',
  'bring',
  'sharp',
  'playground',
  'poison',
  'communion',
  'simple',
  'bring'
];

Iteration #6: Find elements

Let's create a simple array search.

Declare a function named doesWordExist that will take in an array of words as one argument, and a word to search for as the other. Return true if the word exists in the array, otherwise, return false.

You can use the following array to test your solution:

const words = ['machine', 'subset', 'trouble', 'starting', 'matter', 'eating', 'truth', 'disobedience'];

Iteration #7: Count repetition

Declare a function named howManyTimes that will take in an array of words as the first argument, and a word to search for as the second argument. The function will return the number of times that word appears in the array.

You can use the following array to test your solution:

const words = [
  'machine',
  'matter',
  'subset',
  'trouble',
  'starting',
  'matter',
  'eating',
  'matter',
  'truth',
  'disobedience',
  'matter'
];

Bonus - Iteration #8

Bonus - Iteration #8.1: Product of adjacent numbers

Given multiple arrays, find the greatest product of four adjacent numbers.

We consider adjacent any four numbers that are next to each other horizontally or vertically. For example, if we have a 5x5 Matrix like:

[ 1,  2, 3, 4, 5]
[ 1, 20, 3, 4, 5]
[ 1, 20, 3, 4, 5]
[ 1, 20, 3, 4, 5]
[ 1,  4, 3, 4, 5]

The greatest product will be the 20x20x20x4 = 32000.


Declare a function named greatestProduct(matrix) to find it in the 20×20 grid below!

const matrix = [
  [08, 02, 22, 97, 38, 15, 00, 40, 00, 75, 04, 05, 07, 78, 52, 12, 50, 77, 91, 08],
  [49, 49, 99, 40, 17, 81, 18, 57, 60, 87, 17, 40, 98, 43, 69, 48, 04, 56, 62, 00],
  [81, 49, 31, 73, 55, 79, 14, 29, 93, 71, 40, 67, 53, 88, 30, 03, 49, 13, 36, 65],
  [52, 70, 95, 23, 04, 60, 11, 42, 69, 24, 68, 56, 01, 32, 56, 71, 37, 02, 36, 91],
  [22, 31, 16, 71, 51, 67, 63, 89, 41, 92, 36, 54, 22, 40, 40, 28, 66, 33, 13, 80],
  [24, 47, 32, 60, 99, 03, 45, 02, 44, 75, 33, 53, 78, 36, 84, 20, 35, 17, 12, 50],
  [32, 98, 81, 28, 64, 23, 67, 10, 26, 38, 40, 67, 59, 54, 70, 66, 18, 38, 64, 70],
  [67, 26, 20, 68, 02, 62, 12, 20, 95, 63, 94, 39, 63, 08, 40, 91, 66, 49, 94, 21],
  [24, 55, 58, 05, 66, 73, 99, 26, 97, 17, 78, 78, 96, 83, 14, 88, 34, 89, 63, 72],
  [21, 36, 23, 09, 75, 00, 76, 44, 20, 45, 35, 14, 00, 61, 33, 97, 34, 31, 33, 95],
  [78, 17, 53, 28, 22, 75, 31, 67, 15, 94, 03, 80, 04, 62, 16, 14, 09, 53, 56, 92],
  [16, 39, 05, 42, 96, 35, 31, 47, 55, 58, 88, 24, 00, 17, 54, 24, 36, 29, 85, 57],
  [86, 56, 00, 48, 35, 71, 89, 07, 05, 44, 44, 37, 44, 60, 21, 58, 51, 54, 17, 58],
  [19, 80, 81, 68, 05, 94, 47, 69, 28, 73, 92, 13, 86, 52, 17, 77, 04, 89, 55, 40],
  [04, 52, 08, 83, 97, 35, 99, 16, 07, 97, 57, 32, 16, 26, 26, 79, 33, 27, 98, 66],
  [88, 36, 68, 87, 57, 62, 20, 72, 03, 46, 33, 67, 46, 55, 12, 32, 63, 93, 53, 69],
  [04, 42, 16, 73, 38, 25, 39, 11, 24, 94, 72, 18, 08, 46, 29, 32, 40, 62, 76, 36],
  [20, 69, 36, 41, 72, 30, 23, 88, 34, 62, 99, 69, 82, 67, 59, 85, 74, 04, 36, 16],
  [20, 73, 35, 29, 78, 31, 90, 01, 74, 31, 49, 71, 48, 86, 81, 16, 23, 57, 05, 54],
  [01, 70, 54, 71, 83, 51, 54, 69, 16, 92, 33, 48, 61, 43, 52, 01, 89, 19, 67, 48]
];

Bonus - Iteration #8.2: Product of diagonals

Following the logic you've used in iteration #8.1, declare a function called greatestProductOfDiagonals(matrix). It takes a matrix as a parameter and returns the greatest product of any four values layed out diagonally, in either direction.


Happy coding! ❤️