Abstraction is a core concept in all of computer science. Without abstraction, we would still be programming in machine code or worse not have computers in the first place. So IMHO that's a really good question.

**What is ***abstraction*

*Abstracting* something means to *give names* to things, so that the name captures the core of what a function or a whole program does.

One example is given in the book you reference, where it says

Suppose we’re working with turtles, and a common operation we need is
to draw squares. “Draw a square” is an abstraction, or a mental chunk,
of a number of smaller steps. So let’s write a function to capture the
pattern of this “building block”:

Forget about the turtles for a moment and just think of drawing a square. If I tell you to draw a square (on paper), you immediately know what to do:

- draw a square =>
*draw a rectangle with all sides of the same length.*

You can do this without further questions because you know by heart what a *square* is, without me telling you step by step. Here, the word *square* is the *abstraction* of "draw a rectangle with all sides of the same length".

**Abstractions run deep**

But wait, how do you know what a *rectangle* is? Well, that's another abstraction for the following:

*rectangle* => draw two lines parallel to each other, of the same length, and then add another two parallel lines perpendicular to the other two lines, again of the same length but possibly of different length than the first two.

Of course it goes on and on - *lines*, *parallel*, *perpendicular*, *connecting* are all *abstractions* of well-known concepts.

Now, imagine each time you want a rectangle or a square to be drawn you have to give the full definition of a rectangle, or explain lines, parallel lines, perpendicular lines and connecting lines -- it would take far too long to do so.

**The real power of abstraction**

That's the first *power of abstractions:* they make talking and getting things done much easier.

The second power of abstractions comes from the nice property of *composability*: once you have defined abstractions, you can *compose* two or more abstractions to form a new, larger abstraction: say you are tired of drawing squares, but you really want to draw a *house*. Assume we have already defined the *triangle*, so then we can define:

*house* => draw a *square* with a *triangle* on top of it

Next, you want a village:

*village* => draw multiple *houses* next to each other

Oh wait, we want a city -- and we have a new concept *street*:

*city* => draw many *villages* close to each other, fill empty spaces with more *houses*, but leave room for *streets*
*street* => (some definition of street)

and so on...

**How does this all apply to programmming?**

If in the course of planning your program (a process known as *analysis and design*), you find good abstractions to the problem you are trying to solve, your programs become shorter, hence easier to write and - maybe more importantly - easier to read. The way to do this is to try and grasp the major concepts that define your problems -- as in the (simplified) example of drawing a *house*, this was *squares* and *triangles*, to draw a *village* it was *houses*.

In programming, we define abstractions as functions (and some other constructs like classes and modules, but let's focus on functions for now). A function essentially *names* a set of single statements, so a function essentially is an abstraction -- see the examples in your book for details.

**The beauty of it all**

In programming, abstractions can make or break productivity. That's why often times, commonly used functions are collected into *libraries* which can be reused by others. This means you don't have to worry about the details, you only need to understand how to use the ready-made abstractions. Obviously that should make things easier for you, so you can work faster and thus be more productive:

*Example*:

Imagine there is a graphics library called "nicepic" that contains pre-defined functions for all abstractions discussed above: rectangles, squares, triangles, house, village.

Say you want to create a program based on the above abstractions that paints a nice picture of a house, all you have to write is this:

```
import nicepic
draw_house()
```

So that's just two lines of code to get something much more elaborate. Isn't that just wonderful?

Hope this helps.

`calculateFooBar(x, y)`

, you know (or at least have some idea) what that (possibly complex) code does, without caring about reading and understanding all the code that's implementing the function.