# SICP Exercise 1.5

Exercise 1.5. Ben Bitdiddle has invented a test to determine whether the interpreter he is faced with is using applicative-order evaluation or normal-order evaluation. He defines the following two procedures:

(define (p) (p))

(define (test x y) (if (= x 0) 0 y))

Then he evaluates the expression

(test 0 (p))

What behavior will Ben observe with an interpreter that uses applicative-order evaluation? What behavior will he observe with an interpreter that uses normal-order evaluation?

I understand the answer to the exercise; my question lies in how (p) is interpreted versus p. For example, (test 0 (p)) causes the interpreter to hang (which is expected), but (test 0 p) with the above definition immediately evaluates to 0. Why?

Moreover, suppose we changed the definition to (define (p) p). With the given definition, (test 0 (p)) and (test 0 p) both evaluate to 0. Why does this occur? Why doesn't the interpreter hang? I am using Dr. Racket with the SICP package.

-

`p` is a function. `(p)` is a call to a function.

In your interpreter evaluate `p`.

``````p <Return>
==>  P : #function
``````

Now evaluate `(p)`. Make sure you know how to kill your interpreter! (Probably there is a “Stop” button in Dr. Racket.)

``````(p)
``````

Note that nothing happens. Or, at least, nothing visible. The interpreter is spinning away, eliminating tail calls (so, using near 0 memory), calling `p`.

As `p` and `(p)` evaluate to different things, you should expect different behaviour.

As to your second question : You are defining `p` to be a function that returns itself. Again, try evaluating `p` and `(p)` with your `(define (p) p)` and see what you get. My guess (I am using a computer on which I cannot install anything and which has no scheme) is that they will evaluate to the same thing. (I might even bet that `(eq? p (p))` will evaluate to `#t`.)

-
+1 succinct answer. Also try codepad.org. –  Greg Hewgill Jul 4 '12 at 20:06