DEV Community

Cover image for How to Code the Insertion Sort Algorithm in JavaScript
Jared Nielsen
Jared Nielsen

Posted on • Originally published at jarednielsen.com

How to Code the Insertion Sort Algorithm in JavaScript

If you want to think like a programmer, you need to learn algorithms. Learning algorithms improves your problem solving skills by revealing common patterns in software development. In this tutorial, you will learn how to code the insertion sort algorithm in JavaScript.


algorithms
Give yourself an A. Grab your copy of A is for Algorithms


Retrieval Practice

  • What is programming?

  • What is an algorithm?

  • What is computational thinking?

What is Programming?

Programming is the act and art of writing instructions to be executed by a machine. These instructions must follow a predetermined, formalized, set of rules. These rules determine what we can write and how we can use those whats. A programming language is, fundamentally, a combination of logic and syntax, or a set of instructions for writing instructions. So meta!

What is an Algorithm?

An algorithm is a set of clearly defined rules or instructions to be executed by a computer in order to solve a specific problem.

What is Computational Thinking?

Computational thinking is an approach to problem solving where we frame our solution in terms that a computer could also execute. Computational thinking consists of the following stages:

  • Decomposition: Breaking a complex problem into smaller, easier to solve components

  • Pattern recognition: Developing a generalized solution to apply to multiple problems

  • Abstraction: Hiding or ignoring the details of a problem in order to simplify it and make it easier to solve

  • Algorithms: Composing step-by-step instructions to solve a problem

Let's Get Meta

  • Why is it called 'Insertion Sort'?

  • What Problem(s) Does Insertion Sort Solve?

  • What is the Big O of Insertion Sort?

How to Implement the Insertion Sort Algorithm in JavaScript

If we are writing a sorting algorithm, we need to start with something to sort. Let's declare an array of 'unsorted' integers:

const unsorted = [10, 1, 9, 2, 8, 3, 7, 4, 6, 5];
Enter fullscreen mode Exit fullscreen mode

Next, let's declare our insertionSort function:

const insertionSort = (arr) => {
    return arr;
};
Enter fullscreen mode Exit fullscreen mode

Now what?

In order to understand our problem, we need to break it down.

Let's first define it and reframe the problem as acceptance criteria:

GIVEN an array of unsorted numbers

WHEN we check the value of each number and find one out of sequence

THEN we insert that number in its ordinal location in the array

Where have we seen this or something like it before?

Let's use an analogy!

Imagine you were holding a deck of cards and you wanted to put the cards in order. Usig the first half of our unsorted array as an example gives us the following hand:

10, 1, 9, 2, 8
Enter fullscreen mode Exit fullscreen mode

Alt Text

Moving left to right, you would look at the value of the first card and compare it to the value of the second card. In this instance, our first card is 10 and our second card is 1. 10 is greater than 1, so we swap their positions. Now our hand looks like this:

1, 10, 9, 2, 8
Enter fullscreen mode Exit fullscreen mode

Alt Text

Alt Text

Again, moving left to right, we compare the values of our next two cards and see that 10 is greater than 9, so we take 9 out of our hand temporarily and insert it between 1 and 10. Now our hand looks like this:

1, 9, 10, 2, 8
Enter fullscreen mode Exit fullscreen mode

Alt Text

Alt Text

And again, moving left to right, our next two cards are 10 and 2. 10 is greater than 2, but, now, 9 is also greater than 2, so we temporarily remove 2 from our hand and then insert 2 between 1 and 9. Now our hands looks like this:

1, 2, 9, 10, 8
Enter fullscreen mode Exit fullscreen mode

Alt Text

Alt Text

Lastly, we temporarily remove 8 from our hand and compare it to the other cards. 10 is greater than 8, and 9 is greater than 8, but 2 is not. So we insert 8 between 2 and 9. Our sorted hand looks like this:

1, 2, 8, 9, 10
Enter fullscreen mode Exit fullscreen mode

Alt Text

So... how do we translate this to JavaScript?

With our analogy in hand (get it), let's break down, or decompose the problem.

What if our array only contained two values?

const test = [10, 1];
Enter fullscreen mode Exit fullscreen mode

We can see that we need to compare our two values, and if the first value is greater than the second value, we need to swap them.

Our immediate inclination might be something like this:

const insertionSort = (arr) => {

    if (arr[0] > arr[1]) {
        arr[1] = arr[0];
        arr[0] = arr[1];
    }

    return arr;
};
Enter fullscreen mode Exit fullscreen mode

But this won't work. Why?

The result will be the following:

[10, 10]
Enter fullscreen mode Exit fullscreen mode

We could create a new array and return that, or, if we think back to our playing cards analogy, we can temporarily remove a value from the array and then insert it into the array.

const insertionSort = (arr) => {

    if (arr[0] > arr[1]) {
        arr[1] = arr[0];
        arr[0] = arr[1];
    }

    return arr;
};
Enter fullscreen mode Exit fullscreen mode

But which value do we temporarily remove? 0 or 1?

Let's revisit our playing cards analogy again: if we are proceeding left to right through our hand, or array, do we pull the first card or the second?

const unsorted = [10, 1, 9, 2, 8, 3, 7, 4, 6, 5];
Enter fullscreen mode Exit fullscreen mode

If we are using the first half of our array, our inclination is likely to temporarily remove the first card as it is greater. But what if we are working with the latter half of the array, where the first value is less than the next?

3, 7, 4, 6, 5
Enter fullscreen mode Exit fullscreen mode

If we temporarily remove the first card, 3, we would check its value against the next card, 7, see that 3 is less than 7, and simply put it back in its original location.

We could also start with 7, check its value against the previous card, see that 7 is greater than 3, and return it to its location in our hand.

Do you see the pattern? So what about 10 and 1?

We could temporarily remove 10 and check it against the next value, but as we saw above, we could accomplish the same end by starting with the second card, or value, in this case 1.

Long story short, to temporarily remove a value from our array, we simply declare a variable temp and assign it the value stored in arr[1]:

const insertionSort = (arr) => {
    let temp = arr[1];

    if (arr[0] > temp) {
        arr[1] = arr[0];
        arr[0] = temp;
    }

    return arr;
};
Enter fullscreen mode Exit fullscreen mode

Now that we recognize the pattern, how do we abstract, or model, this?

What do I mean by that?

As soon as we declared temp, we entered the realm of abstraction. arr[1] and arr[2] both refer to specific values in our array. But temp can refer to any value we assign to it. In our conditional statement, we are still making specific reference to arr[0].

What is arr[0] in relation to arr[1]?

It's the previous index in our array, so let's declare a new variable, prev and assign it a value of 0.

And what is temp in relation to prev?

prev + 1

When we refactor our insertionSort function, we only need to make reference to specific value in array, arr[1]. The rest are abstractions.

const insertionSort = (arr) => {
    let temp = arr[1];
    let prev = 0;

    if (arr[prev] > temp) {
        arr[1] = arr[prev];
        arr[prev] = temp;
    }

    return arr;
};
Enter fullscreen mode Exit fullscreen mode

Now it's time for the last stage of computational thinking: let's get algorithmic!

Our current solution is great for two values, but how do we sort an array of multiple values?

For each value in the array, we need to check it against the previous values and insert it in ordinal sequence...

Let's refactor our function with iteration. Rather than i, let's use a descriptive iterator variable, curr, short for current, to help us see what's happening.

What value do we assign to curr?

We might be inclined, by force of habit and inertia, to initialize our iterator variable with 0, but let's recall our card analogy above. We don't need to start with the first card in our hand when starting with the second card achieves the same end and is more efficient. So... let's initialize our for loop with 1.

We also need to update our reference to arr[1] with a arr[curr]:

const insertionSort = (arr) => {
    for (let curr = 1; curr < arr.length; curr++) {
        let temp = arr[curr];
        let prev = 0;

        if (arr[prev] > temp) {
            arr[curr] = arr[prev];
            arr[prev] = temp;
        }
    }
    return arr;
};
Enter fullscreen mode Exit fullscreen mode

What happens when we run our insertionSort function?

[  1, 10,  9, 2,  8,  3, 7,  4,  6, 5 ]
Enter fullscreen mode Exit fullscreen mode

Our first two numbers swapped, but nothing else. Why?

We need to algorithmically determine the value of prev. In our conditional statement, we are only comparing each number against the value stored in arr[0], which, after the first iteration is 1.

If prev is the value previous to curr, how can we determine it without hard coding a value?

let prev = curr - 1;
Enter fullscreen mode Exit fullscreen mode

Our algorithm now looks like this:

const insertionSort = (arr) => {
    for (let curr = 1; curr < arr.length; curr++) {
        let temp = arr[curr];
        let prev = curr - 1;

        if (arr[prev] > temp) {
            arr[curr] = arr[prev];
            arr[prev] = temp;
        }
    }
    return arr;
};
Enter fullscreen mode Exit fullscreen mode

If we run it, the result is the following:

[ 1,  9,  2,  8,  3,  7,  4,  6,  5, 10 ]
Enter fullscreen mode Exit fullscreen mode

What is going on here?

We're only checking values forward, not back, so for each iteration, arr[prev] is 10, and we swap all of the values with it until we reach the end of the array.

That's cool if our goal is just to sort the largest value.

Let's visualize this...

Here's our unsorted array:

10, 1, 9, 2, 8, 3, 7, 4, 6, 5
Enter fullscreen mode Exit fullscreen mode

In the first iteration, the values stored in our variables are the following:

curr arr[curr] && temp prev arr[prev]
1 1 0 10

And our insertionSort function returns the following:

[ 1,  9,  10,  2,  8,  3,  7,  4,  6,  5 ]
Enter fullscreen mode Exit fullscreen mode

In the second iteration, the values stored in our variables are the following:

curr arr[curr] && temp prev arr[prev]
2 9 1 10

And our insertionSort function returns the following:

[ 1,  9,  2,  10,  8,  3,  7,  4,  6,  5 ]
Enter fullscreen mode Exit fullscreen mode

In the third iteration, the values stored in our variables are the following:

curr arr[curr] && temp prev arr[prev]
3 2 2 10

And our insertionSort function returns the following:

[ 1,  9,  2,  8, 10,  3,  7,  4,  6,  5 ]
Enter fullscreen mode Exit fullscreen mode

In the fourth iteration, the values stored in our variables are the following:

curr arr[curr] && temp prev arr[prev]
4 8 3 10

And our insertionSort function returns the following:

[ 1,  9,  2,  8,  3, 10, 7,  4,  6, 5 ]
Enter fullscreen mode Exit fullscreen mode

In the fifth iteration, the values stored in our variables are the following:

curr arr[curr] && temp prev arr[prev]
5 3 4 10

And our insertionSort function returns the following:

[ 1,  9,  2, 8,  3,  7, 10,  4,  6, 5 ]
Enter fullscreen mode Exit fullscreen mode

In the sixth iteration, the values stored in our variables are the following:

curr arr[curr] && temp prev arr[prev]
6 7 5 10

And our insertionSort function returns the following:

[ 1,  9,  2, 8,  3,  7, 4, 10,  6, 5 ]
Enter fullscreen mode Exit fullscreen mode

In the seventh iteration, the values stored in our variables are the following:

curr arr[curr] && temp prev arr[prev]
7 4 6 10

And our insertionSort function returns the following:

[ 1,  9,  2, 8,  3,  7, 4,  6, 10, 5 ]
Enter fullscreen mode Exit fullscreen mode

In the eighth iteration, the values stored in our variables are the following:

curr arr[curr] && temp prev arr[prev]
8 6 7 10

And our insertionSort function returns the following:

[ 1,  9,  2, 8,  3,  7, 4,  6,  5, 10 ]
Enter fullscreen mode Exit fullscreen mode

In the ninth and final iteration, the values stored in our variables are the following:

curr arr[curr] && temp prev arr[prev]
9 5 8 10

And our insertionSort function returns the following:

[ 1,  9,  2, 8,  3,  7, 4,  6,  5, 10 ]
Enter fullscreen mode Exit fullscreen mode

Do you see the pattern?

What's the solution?

With every iteration forward, we need to word backwards and sort the preceding numbers as well.

What control flow statement easily allows us to count down?

while

Which of the values listed in our tables above do we want to use as our condition?

prev

Why?

Because abstraction!

With each iteration of our while loop, we want to check the value stored in the previous array index. And with each iteraton of our for loop, we reassign the value of prev to curr - 1.

Let's refactor our function with a while loop:

const insertionSort = (arr) => {
    for (let curr = 1; curr < arr.length; curr++) {
        let temp = arr[curr];
        let prev = curr - 1;

        while(prev >=0) {
            if (arr[prev] > temp) {
                arr[curr] = arr[prev];
                arr[prev] = temp;
            }
            prev = prev - 1;
        }
    }
    return arr;
};
Enter fullscreen mode Exit fullscreen mode

NOTE: prev = prev - 1; is outside the if statement. If we placed it inside, we would get caught in an endless loop as there are definitely iterations where arr[prev] will be less than temp.

Running insertionSort now returns:

[ 1, 2, 2, 3, 3, 4, 4, 5, 5, 6 ]
Enter fullscreen mode Exit fullscreen mode

Well... it's sorted. But also shorted. What's going on?

When we decrement prev with each iteration of our while loop, it is no longer coupled with curr. What is curr, abstractly?

prev + 1

Let's update that in our function...

const insertionSort = (arr) => {
    for (let curr = 1; curr < arr.length; curr++) {
        let temp = arr[curr];
        let prev = curr - 1;    

        while(prev >= 0) {
            if (arr[prev] > temp) {
                arr[prev + 1] = arr[prev];
                arr[prev] = temp;
            }
            prev = prev - 1;
        }
    }
    return arr;
};
Enter fullscreen mode Exit fullscreen mode

Now when we run our insertionSort function, it returns:

[
   1,  2,  3,
   4,  5,  6,
   7,  8,  9,
  10
]
Enter fullscreen mode Exit fullscreen mode

Reflection

  • Why is it called 'Insertion Sort'?

  • What Problem(s) Does Insertion Sort Solve?

  • What is the Big O of Insertion Sort?

Why is it Called 'Insertion Sort'?

Insertion Sort gets its name from the approach to sorting where a numerical value is inserted into an array in ordinal sequence.

What Problem(s) Does Insertion Sort Solve?

Insertion Sort is useful, and ideal, when the data to be sorted is small or nearly sorted.

What is the Big O of Insertion Sort?

What is the Big O of Insertion Sort? Because we are working with nested iteration, it's O(n^2).

Learn Insertion Sort Algorithm in JavaScript

If you want to think like a programmer, you need to learn algorithms. Learning algorithms improves your problem solving skills by revealing common patterns in software development. In this tutorial, you will learn the insertion sort algorithm in JavaScript.


If you want to stay in the loop, sign up for my newsletter, The Solution.


Top comments (1)

Collapse
 
devfemibadmus profile image
Dev Femi Badmus

Thanks allot 🥰