This is one of the weirder (and possibly one of the more wonderful) examples of exploiting first-class functions in Scheme. Something similar is also in the Little Schemer, which is where I first saw it, and I remember scratching my head for days over it. Let me see if I can explain it in a way that makes sense, but I apologize if it's not clear.

I assume you understand the primitives `cons`

, `car`

, and `cdr`

as they are implemented in Scheme already, but just to remind you: `cons`

constructs a pair, `car`

selects the first component of the pair and returns it, and `cdr`

selects the second component and returns it. Here's a simple example of using these functions:

```
> (cons 1 2)
(1 . 2)
> (car (cons 1 2))
1
> (cdr (cons 1 2))
2
```

The version of `cons`

, `car`

, and `cdr`

that you've pasted should behave exactly the same way. I'll try to show you how.

First of all, `car`

and `cdr`

are not defined within the scope of `cons`

. In your snippet of code, all three (`cons`

, `car`

, and `cdr`

) are defined at the top-level. The function `dispatch`

is the only one that is defined inside `cons`

.

The function `cons`

takes two arguments and returns a function of one argument. What's important about this is that those two arguments are visible to the inner function `dispatch`

, which is what is being returned. I'll get to that in a moment.

As I said in my reminder, `cons`

constructs a pair. This version of `cons`

should do the same thing, but instead it's returning a function! That's ok, we don't really care how the pair is implemented or laid out in memory, so long as we can get at the first and second components.

So with this new function-based pair, we need to be able to call `car`

and pass the pair as an argument, and get the first component. In the definition of `car`

, this argument is called `z`

. If you were to execute the same REPL session I had above with these new `cons`

,`car`

, and `cdr`

functions, the argument `z`

in `car`

will be bound to the function-based pair, which is what `cons`

returns, which is `dispatch`

. It's confusing, but just think it through carefully and you'll see.

Based on the implementation of `car`

, it appears to be that it take a function of one argument, and applies it to the number `0`

. So it's applying `dispatch`

to `0`

, and as you can see from the definition of `dispatch`

, that's what we want. The `cond`

inside there compares `m`

with `0`

and `1`

and returns either `x`

or `y`

. In this case, it returns `x`

, which is the first argument to `cons`

, in other words the first component of the pair! So `car`

selects the first component, just as the normal primitive does in Scheme.

If you follow this same logic for `cdr`

, you'll see that it behaves almost the same way, but returns the second argument to `cons`

, `y`

, which is the second component of the pair.

There are a couple of things that might help you understand this better. One is to go back to the description of the substitution model of evaluation in Chapter 1. If you carefully and meticulously follow that substitution model for some very simple example of using these functions, you'll see that they work.

Another way, which is less tedious, is to try playing with the `dispatch`

function directly at the REPL. Below, the variable `p`

is defined to refer to the `dispatch`

function returned by `cons`

.

```
> (define p (cons 1 2))
#<function> ;; what the REPL prints here will be implementation specific
> (p 0)
1
> (p 1)
2
```