Great question. For the benefit of those without a functioning DrRacket installation ~~(myself included)~~ I'll try to answer it.

First, let's use some sane (short) variable names, easily trackable by a human eye/mind:

```
((lambda (h) ; A.
(h h)) ; apply h to h
(lambda (g)
(lambda (lst)
(if (null? lst) 0
(add1
((g g) (cdr lst)))))))
```

The first lambda term is what's known as little omega, or **U** combinator. When applied to something, it causes that term's self-application. Thus the above is equivalent to

```
(let ((h (lambda (g)
(lambda (lst)
(if (null? lst) 0
(add1 ((g g) (cdr lst))))))))
(h h))
```

When `h`

is applied to `h`

, new binding is formed:

```
(let ((h (lambda (g)
(lambda (lst)
(if (null? lst) 0
(add1 ((g g) (cdr lst))))))))
(let ((g h))
(lambda (lst)
(if (null? lst) 0
(add1 ((g g) (cdr lst)))))))
```

Now there's nothing to apply anymore, so the inner `lambda`

form is returned — along with the hidden linkages to the environment frames (i.e. those `let`

bindings) up above it.

This pairing of a lambda expression with its defining environment is known as closure. To the outside world it is just another function of one parameter, `lst`

. No more reduction steps left to perform there at the moment.

Now, when that closure — our `list-length`

function — will be called, execution will eventually get to the point of `(g g)`

self-application, and the same reduction steps as outlined above will again be performed (recalculating *the* *same* closure). But not earlier.

Now, the authors of that book want to arrive at the **Y** combinator, so they apply some code transformations to the first expression, to somehow arrange for that self-application `(g g)`

to be performed automatically — so we may write the recursive function application in the normal manner, `(f x)`

, instead of having to write it as `((g g) x)`

for all recursive calls:

```
((lambda (h) ; B.
(h h)) ; apply h to h
(lambda (g)
((lambda (f) ; 'f' to become bound to '(g g)',
(lambda (lst)
(if (null? lst) 0
(add1 (f (cdr lst)))))) ; here: (f x) instead of ((g g) x)!
(g g)))) ; (this is not quite right)
```

Now after few reduction steps we arrive at

```
(let ((h (lambda (g)
((lambda (f)
(lambda (lst)
(if (null? lst) 0
(add1 (f (cdr lst))))))
(g g)))))
(let ((g h))
((lambda (f)
(lambda (lst)
(if (null? lst) 0
(add1 (f (cdr lst))))))
(g g))))
```

which is equivalent to

```
(let ((h (lambda (g)
((lambda (f)
(lambda (lst)
(if (null? lst) 0
(add1 (f (cdr lst))))))
(g g)))))
(let ((g h))
(let ((f (g g))) ; problem! (under applicative-order evaluation)
(lambda (lst)
(if (null? lst) 0
(add1 (f (cdr lst))))))))
```

And here comes trouble: the self-application of `(g g)`

is performed too early, *before* that inner lambda can be even returned, as a closure, to the run-time system. We only want it to be reduced when the execution gets to that point *inside* the lambda expression, *after* the closure was called. To have it reduced before the closure is even created is ridiculous. A *subtle* error. :)

Of course, since `g`

is bound to `h`

, `(g g)`

is reduced to `(h h)`

and we're back again where we started, applying `h`

to `h`

. Looping.

Of course the authors are aware of this. They want *us* to understand it too.

So the culprit is simple — it is the applicative order of evaluation: *evaluating* the argument *before* the binding is formed of the function's formal parameter and its argument's *value*.

That code transformation wasn't quite right, then. It would've worked under normal order where arguments aren't evaluated in advance.

This is remedied easily enough by "eta-expansion", which delays the application until the actual call point: `(lambda (x) ((g g) x))`

actually says: "**will** call `((g g) x)`

when called upon with an argument of `x`

".

And this is actually what that code transformation should have been in the first place:

```
((lambda (h) ; C.
(h h)) ; apply h to h
(lambda (g)
((lambda (f) ; 'f' to become bound to '(lambda (x) ((g g) x))',
(lambda (lst)
(if (null? lst) 0
(add1 (f (cdr lst)))))) ; here: (f x) instead of ((g g) x)
(lambda (x) ((g g) x)))))
```

Now that next reduction step can be performed:

```
(let ((h (lambda (g)
((lambda (f)
(lambda (lst)
(if (null? lst) 0
(add1 (f (cdr lst))))))
(lambda (x) ((g g) x))))))
(let ((g h))
(let ((f (lambda (x) ((g g) x)))) ; here it's OK
(lambda (lst)
(if (null? lst) 0
(add1 (f (cdr lst))))))))
```

and the closure `(lambda (lst) ...)`

is formed and returned without a problem, and when `(f (cdr lst))`

is called (inside the closure) it is reduced to `((g g) (cdr lst))`

just as we wanted it to be.

Lastly, we notice that `(lambda (f) (lambda (lst ...))`

expression in `C.`

doesn't depend on any of the `h`

and `g`

. So we can take it out, make it an argument, and be left with ... the **Y** combinator:

```
( ( (lambda (rec) ; D.
( (lambda (h) (h h))
(lambda (g)
(rec (lambda (x) ((g g) x)))))) ; applicative-order Y combinator
(lambda (f)
(lambda (lst)
(if (null? lst) 0
(add1 (f (cdr lst)))))) )
(list 1 2 3) ) ; ==> 3
```

So now, calling **Y** on a function is equivalent to making a recursive definition out of it:

```
( y (lambda (f) (lambda (x) .... (f x) .... )) )
=== define f = (lambda (x) .... (f x) .... )
```

... but using `letrec`

(or named let) is *better* — more efficient, defining the closure in self-referential environment frame. The whole **Y** thing is a theoretical exercise for the systems where that is not possible — i.e. where it is not possible to *name* things, to create *bindings* with names *"pointing"* to things, *referring* to things.

*Incidentally, the ability to* point *to things is what distinguishes the higher primates from the rest of the animal kingdom ⁄ living creatures, or so I hear.* :)